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Heteromorphic Life Histories of Certain Marine Algae as Adaptations to Variations in Herbivory Jane Lubchenco; John Cubit Ecology, Vol. 61, No. 3. (Jun., 1980), pp. 676-687. Stable URL: http://links.jstor.org/sici?sici=0012-9658%28198006%2961%3A3%3C676%3AHLHOCM%3E2.0.CO%3B2-H Ecology is currently published by Ecological Society of America. Your use of the JSTOR archive indicates your acceptance of JSTOR's Terms and Conditions of Use, available at http://www.jstor.org/about/terms.html. JSTOR's Terms and Conditions of Use provides, in part, that unless you have obtained prior permission, you may not download an entire issue of a journal or multiple copies of articles, and you may use content in the JSTOR archive only for your personal, non-commercial use. Please contact the publisher regarding any further use of this work. Publisher contact information may be obtained at http://www.jstor.org/journals/esa.html. 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For more information regarding JSTOR, please contact [email protected]. http://www.jstor.org Mon Mar 24 17:02:11 2008 Ecoloyy, 61(3), 1980, pp. 676-687 1980 by the Ecological Society of America HETEROMORPHIC LIFE HISTORIES O F CERTAIN MARINE ALGAE AS ADAPTATIONS TO VARIATIONS I N HERBIVORY1 JANEL U B C H E N C O ~ ' ~ Depurtment of Zoology, Oregon State University, Corvullis, Oregon 97331 U S A AND JOHNCUBIT^'^ Depurtment of Biology, University of Oregon, Eugene, Oregon 97403 U S A Abstract. Many of the annual or ephemeral algae of the mid to high intertidal zones have heteromorphic life histories, existing as upright morphs during seasonal algal blooms and as crustose or boring morphs during other portions of the year. Experimental removal of herbivores on the coasts of New England and Oregon resulted in the occurrence of the upright morphs in the times of year when they were normally absent (summer in our areas), demonstrating that such uprights can survive the summertime physical regime (contrary to earlier speculation). We suggest that the upright and crustose or boring stages of these algae represent mutually exclusive adaptations to fluctuations in grazing pressure: the upright stages are adapted for high rates of growth and reproduction when grazing pressure is low, and the crustose and boring stages are adapted for surviving through times of high grazing pressure. We predict isomorphic species of algae would predominate in these sorts of habitats if grazing pressure were more constant. Key words: algae; Bangia; Codiolum; Conchocelis; herbivores; heteromorphology; life histories; Petalonia; Porphyra; Ralfsia; Scytosiphon; Ulothrix; Urospora. Heteromorphic algae exhibit a high degree o f independence and differentiationamong the stages o f their life cycles. Most o f the particular heteromorphic algae discussed in this paper have two separate, in some cases self-propagating, and ecologically distinct phases which are so dissimilar in appearance that until recently they had been classified as separate species, and, in some cases, had been placed in separate families or orders. Istock (1967) has proposed that evolutionarily such life cycles should be inherently unstable: as selection acts independently on the separate stages, one stage should eventually be eliminated or reduced in favor o f the other. He cites as examples the loss or reduction o f larval or adult stages in some insects, cnidarians, and amphibians. Another more pervasive set o f examples is the loss o f the free-living, haploid, gametophyte stage from the life cycles o f most plants and animals. However, Istock (1967, 1970) points out there are a number o f counterexamples with apparently long- ' Manuscript received 14 February 1979; accepted 1 June 1979; final version received 29 August 1979. Order of authorship determined by coin toss. In previous publications, J. Lubchenco Menge. Present address: Smithsonian Tropical Research Institute, APO Miami, Florida 34002 USA. established, stable life cycles involving several ecologically distinct stages. T o these we add certain heteromorphic algae, which by Istock's (1967) criteria should be particularly evolutionarily unstable: the stages are often found under different growing conditions, and some, rather than being larva-like developmental stages, are capable o f independent self-propagation that allows them to persist indefinitely in the absence o f any other stage. Algae with various types o f heteromorphic life cycles are both phylogenetically and ecologically widespread: heteromorphic algae occur in the three major divisions o f macroalgae (Chlorophyta, Phaeophyta, and Rhodophyta) and are found in a variety o f habitats. However, in this paper we concentrate on those species o f heteromorphic algae which comprise much o f the macroalgal portions o f seasonal or ephemeral blooms in the mid to high intertidal zones o f rocky shores. These species are in the following divisions and genera: Chlorophyta: Ulothrix and Urospora; Phaeophyta: Petalonia and Scytosiphon; Rhodophyta: Bangia and Porphyra. Although the algae in this group are taxonomically quite different,their life cycles and morphologies have much in common. Each species has two primary stages: the stage which appears in the periodic algal blooms is an upright filament, tube, or blade; the other is a nonupright crust or boring stage. ( A third stage, a small filamentous tuft, is also known for Petalonia and Scytosiphon.) The convprgence in June 1980 HERBIVORY AND ALGAL LIFE HISTORIES the patterns o f life cycles o f these algae suggests their forms and life histories may be adaptations to a common set o f selective factors; thus, these plants provide a system to examine the mechanisms by which complex life cycles are selected and maintained. The main question addressed in this paper is the following: what is the adaptive significance o f the heteromorphic life cycles o f these intertidal algae? An explanation already proposed is that the nonupright morphs are perennating stages which survive through the physically harsh seasons when the upright morphs are killed by such stresses as desiccation, insolation, and high temperatures (Conway et al. 1976). A second hypothesis occurred to each o f us during our independent studies on the effects o f herbivores on benthic marine algae. W e observed that in several heteromorphic species the upright morphs could survive in physically harsh seasons i f protected from herbivores, and that the nonupright morphs were either themselves grazer-resistant or specifically exploit microhabitats which we infer protect them from grazing. In this paper we suggest the hypothesis that spatial and temporal variations in grazing play a major role in the selection and continued maintenance o f the different morphologies in these life cycles. In the following sections we present the results o f experiments testing this hypothesis on the east and west coasts o f the United States: in New England (studies o f J.L.) and in Oregon (studies o f J.C.). Alternate hypotheses and ways to test them are suggested in the discussion section. I f our interpretations are correct, we predict that in less variable environments algae with heteromorphic life cycles would not be maintained in such abundance and, instead, algae with isomorphic life cycles would increase in relative proportion. 677 SEASONAL CYCLES OF : HERBIVORE ACTIVITY ULOTHRIX k m B m A PORPHYRA vL ' % O N D J F M A M J J A S O FIG. 1 . Subjective evaluations of percent of gastropod herbivore individuals active and of the relative abundance of the upright morphs of five heteromorphic algal species on the New England coast during the year. The herbivores are primarily Littorinu littorea, but also include other snails: L. obtusuta, L . saxatilis, Lucunu vinctu, Murgurites helicinu, and Acmaea testudinulis. Herbivores not included are isopods, amphipods, and diptera. Each algal species was recorded as being common (C), present (P), or absent (A) at each study area at least monthly for 3 yr. Study areas where gastropod herbivores are common (protected to intermediate in exposure to wave action) are indicated by the solid portions. Areas where gastropod herbivores are rare or absent (exposed sites) are indicated by cross-hatching. Scytosiphon, Petuloniu, and Porphyra are able to persist longer in exposed sites. Crustacean herbivores are often abundant at more exposed sites. Their effect on algae is yet to be determined. The life histories o f these algae are as follows: 1 ) Petalonia fascia (0. F . Miill.) 0 . Kuntze and Scytosiphon lamentaria (Lyngb.) Link (Phaeophyta: Scytosiphonaceae). The upright morphs o f both o f these algae are "winter annuals" in New England (Fig. 1 , Taylor 1957, Kingsbury 1969). The upright blades of Petalonia (7.545 cm long) and upright tubes o f Scytosiphon (15-70 cm long) appear in tide pools and on the shore from N e w England studies October-November until March-May. Both species Description of sites and species studied.-The het- probably alternate (but not in an obligate sense) with eromorphic algal species treated in the studies o f the tar-like crusts previously thought to be species o f Ralfrocky shores o f New England are the brown algae sia (Phaeophyta: Ralfsiaceae) and perhaps with small Petulonia fascia (0.F . Miill.) 0 . Kuntze and Scyto- filamentous tufts, as has been shown for these species siphon lomentaria (Lyngb.)Link, the red algae Bangia elsewhere (Edelstein et al. 1970, Rhodes and Connell fuscopurpurea (Dillw.) Lyngb., Porphyra miniata (C. 1973, review by Wynne and Loiseaux 1976). The seaAg.) C. Ag., P. linearis Grev., and P. umbilicalis ( L . ) sonal occurrence o f the ralfsioid crust morph is diffiJ. Ag., and the possibly heteromorphic green alga Ulo- cult to assess accurately because these crusts are difthrix flucca (Dillw.) Thur. in LeJolis. Observations ficult to distinguish in the field from other, valid were made on all o f these species, but experiments Ralfsia species. The crustose morph, hereafter termed focused on the two brown algae Petulonia and Scy- "Ralfsia," appears to be more abundant in the sumtosiphon. These plants were studied at four study mer than in the winter in New England. areas in Massachusetts ( M A ) and Maine ( M E ) from Petalonia and Scytosiphon differ somewhat in the fall 1971 until summer 1977. The areas are nonestua- specifics o f their life cycles, in particular in the ploidy rine and range in exposure to wave action from very levels. According to Nakamura and Tatewaki (1975), protected to very exposed as follows: Canoe Beach Scytosiphon tubes are haploid and produce gametes. Cove, Nahant, M A ; Grindstone Neck, ME; East These gametes do one o f three things: ( 1 ) develop parPoint, Nahant, MA; and Pemaquid Point, ME. All thenogenetically into more haploid tubes, ( 2 ) develop areas are described in detail in J . Lubchenco Menge parthenogenetically into haploid "Ralfsiu" crusts or tufts or (3) fuse, with the zygote developing into a (1975)and B. Menge (1976). 678 JANE LUBCHENCO AND JOHN CUBIT diploid "Ralfsia" crust or tuft. Both haploid and diploid crusts or tufts produce zooids which develop into upright tubes. Meiosis occurs only when diploid crusts or tufts form zooids. Wynne (1969) found that his "Ralfsia" could also produce more "Ralfsia" crusts. Thus in this species the upright morph is haploid while the other can be either diploid or haploid, indicating a partial decoupling o f the morphological and genetic components. This decoupling is complete in Petalonia, where all stages (crusts, tufts, and blades) appear to be of the same ploidy number. No evidence o f sexuality has been reported. "Ralfsia" crusts or tufts produce zooids which develop into either more "Ralfsia," or tufts or Petalonia blades. Blades produce swarmers which develop into either crusts, tufts, or blades (Wynne 1969, Wynne and Loiseaux 1976). Neither o f these species represents the classical picture o f a strict alternation o f generations (haploid with diploid). More significantly, both species appear to possess tremendous morphological flexibility, each morph being able to produce either more individuals like itself or the other alternate morph. In other words, neither genetic nor morphological alternation is obligate. W h y then are there two distinct morphs, each with this plasticity? Proximate factors affecting which morph is produced have been investigated in the laboratory. In numerous culture studies, blades o f Petalonia and tubes o f Scytosiphon were found to be produced mainly under simulated "wintertime conditions ," i.e., short daylength photoperiods and cool temperatures. The "Ralfsia" crusts or tufts were obtained under laboratory "summertime conditions," i.e., long daylength photoperiods and warm temperatures (Wynne 1969, Roeleveld et al. 1974, Dring and Luning 1975, Nakamura and Tatewaki 1975). It seems significant that in these laboratory culturing experiments there was usually some variation in the response o f plants to temperature and photoperiod; that is, a small percentage o f the progeny became the "wrong" morph for a particular set o f conditions (Wynne 1969, Roeleveld et al. 1974). For example, in three o f Wynne's experiments with Petalonia, 5-20%, 5-10%, and 0% o f the progeny developed into blades under summertime conditions (18"-1YC, 16 h light-8 h dark). The potential significance o f this variation will be discussed below. Both species' laboratory behavior generally corresponds to their seasonal occurrence in New England: uprights are produced under wintertime conditions, and crusts appear primarily under summertime conditions. 2) Bangia fuscopurpurea (Dillw.) Lyngb. (Rhodophyta: Bangiaceae). This species has two very different phases in its life history: upright, macroscopic plants which are uniseriate or multiseriate filaments, and an endolithic fila- Ecology, Vol. 61, No. 3 mentous form previously known as "Conchocelis. " Upright plants are dioecious and produce two o f three possible types o f spores: ( 1 ) "monospores" or "neutral spores" which develop into more upright filaments and one o f the following types o f spores (2) "carpospores" or "alpha spores" which germinate to give rise to the "Conchocelis" phase, or (3) "spermatia" or "beta spores" that presumably act as male gametes and fuse with the cells that develop into carpospores. The "Conchocelis" phase produces two types o f spores: ( 1 ) "monospores" which develop into more ' 'Conchocelis " plants, and (2) ' 'conchospores' ' which develop into the macroscopic upright phase (Sommerfeld and Nichols 1970). Both photoperiodism (Richardson and Dixon 1968, Dixon and Richardson 1970, Richardson 1970) and temperature (Sommerfeld and Nichols 1973) have been shown to control the formations and release o f spores o f both phases o f the life history in the laboratory. In New England, the upright Bangia filaments measure =lo-20 mm in length and 0.15 mm in diameter and usually appear in DecemberFebruary and persist through March-May (Fig. 1). The seasonal occurrence o f the "Conchocelis" phase is not known; however, the plants have been found in intertidal mollusc and barnacle shells (Bird 1973). The "Conchocelis" phase is thought to be perennating. 3) Porphyra umbilicalis ( L . ) J . Ag., P. miniata (C. Ag.) C. Ag., and P . linearis Grev. As in Bangia, the life history o f these species involves two different phases with different morphologies. The macroscopic Porphyra thalli discussed here are leafy sheets usually ranging in size from 3 to 15 cm long, are haploid, and alternate with a "Conchocelis" phase (as described for Bangia) which is usually diploid and which bores into and lives in calcareous substrates. There exists considerable variation among the species with respect to seasonal occurrence and specifics o f the life history (Conway 1964, Edelstein and McLachlan 1966, Chen et al. 1970, Bird et al. 1972, Bird 1973, Bold and Wynne 1978, Hawkes 1978). The foliose phase o f P. linearis is a high intertidal winter annual. Since no neutral spores are formed by the blades and the basal portion does not perennate, blades must come solely from conchospores. Conchospores are released only at 13°C in culture, but can be found throughout the year in the intertidal. The "Conchocelis" phase has been found in subtidal mussel (Modiolus modiolus) shells (Bird et al. 1972, Bird 1973). The foliose thallus o f P. miniata occurs in the mid and low intertidal and subtidal regions from spring to summer. All blades apparently come from conchospores. Conchospore release is triggered in the laboratory at temperatures <13"C (Chen et al. 1970). P. umbilicalis has several upright forms: ( 1 ) perennial rosettes present in the high zone (Edelstein and McLachlan 1966), (2) an elongated morph that appears in the winter in mid zones, and (3) a persistent blade June 1980 HERBIVORY A N D ALGAL LIFE HISTORIES phase that occurs in the low intertidal and reproduces by neutral spores to form more blades (Conway 1964, Chen et al. 1970). In the areas reported in this paper, foliose uprights usually appeared in October-November and persisted through May-June where herbivores were present or occurred throughout the year where herbivores were absent or rare, for example, at exposed areas (Fig. 1 ) . Species o f Porphyra could not always be distinguished and are lumped together here. 4 ) Ulothrix flacca (Dillw.) Thur. in LeJolis (Chlorophyta: Ulotrichaceae). Both isomorphic and heteromorphic life cycles have been described for U . flacca elsewhere. Perrot (1972) suggests that in France it is really two separate species, one isomorphic and occurring in the very high intertidal zone and the other heteromorphic and occurring lower. The isomorphic species, termed "Form A" by Perrot, has upright, filamentous gametophytes and sporophytes. Each stage reproduces to form either more plants o f the same or the alternate stage. The heteromorphic species, "Form B," has dioecious, upright, filamentous gametophytes which produce two types o f cells: ( 1 ) zoospores which develop directly into more upright gametophytes and (2)gametes which fuse to form a zygote that develops into a discoid sporophyte resembling the green prostrate Codiolum. This Codiolum-like stage produces aplanospores which develop directly into upright gametophytes. Both photoperiod and temperature are involved as cues in this nonobligate alternation. The life histories o f the New England U .flacca have not been investigated, but circumstantial evidence suggests that at least the heteromorphic form is present. Ulothrix occurs as long, slender filaments (10-70 m m long, 0.15 mm in diameter) forming dense mats which are common throughout the intertidal region from October-November to March-May (Fig. 1). When Ulothrix disappears during the spring, "Codiolum" appears and persists throughout the summer and fall. Herbivore occurrence and algal preference.-The most abundant herbivore in the New England rocky intertidal zone is the common periwinkle snail Littorina littorea which occurs in tide pools and on emergent substrata where these heteromorphic algae are found ( J . Lubchenco Menge 1975, Lubchenco 1978). Littorina is usually active from spring (March-May) to late fall (October-November, Fig. I), at just the time when the upright morphs o f Scytosiphon, Petalonia, Bangia, Porphyra, and Ulothrix are absent (Fig. 1). Laboratory preference experiments indicate that Littorina will readily eat the upright morphs o f all o f these species, but not the crustose forms (Lubchenco 1978). Crusts like these are not totally herbivore resistant, but are much less preferred than are the upright morphs or many other nonheteromorphic upright species. 679 "t;kLp, p--X, 6. Roof '0°1 x--K'x 50 ; u C. h. w 6 9 enclosure 0-0 X-- lo]0 U x,., ; ! 50 O , ,* 'x' Petalonia 0-, ,o S@asiphm ..., \ W 'x--f II , x---x A, , , I, , \ p--x--x--x, , ; , , , X X , I '\ I Ephememl Algae ;x' D. Herbivore 'x,, Exclusion I x--x i \ "\x-.X" x' p.. . . , . . c . A M J J A S O N D J F M A M J J A 1973 1974 FIG. 2. Effect of herbivores on the occurrence of Petaloniu and Scytosiphon in the high intertidal zone at Grindstone Neck, Maine. The numbers below each treatment title indicate the mean number of grazers present and 95% confidence interval. L.1. = Littorina littoreu, L.o. = L . obtusata, L.s. = L . saxutilis. Ephemeral algae are those plants that usually persist for short periods of time during the year. Petuloniu and Scytosiphon are ephemeral species by this definition, but are separated from the rest of the ephemeral algae since they are the focus of this experiment. The other ephemeral species appearing in this experiment include some heteromorphic and some nonheteromorphic uprights: Bangia fuscopurpureu, Dumontia incrussata, Porphyra spp., Rhizoclonium tortuosum. Spongomorpha sp., and Ulothrixjucca. Separate percent cover values for each species were usually taken; occasionally some species were mixed together so thoroughly that it was necessary to lump them together (as for Scytosiphon and Petulonia in A and B). The approximate period of seasonal inactivity of the herbivore, 1,ittorinu littoreu, is indicated by the bar at the top of the figure. See text for details of treatments. Field herbivore exclusions: design.-During the course o f a general investigation o f the effects of rocky intertidal herbivores on algae in New England, a series o f 10 x 10 x 3 or 10 x 10 x 5 cm stainless steel mesh cages were attached to the rock and used to exclude or enclose various herbivores (see J. Lubchenco Ecology, Vol. 61, No. 3 JANE LUBCHENCO A N D JOHN CUBIT Herbiwres inactive '"1 0 A. CONTROL D HERBIVORE C. L F HERB. EXCL., LITTOREA ENCLOSURE E!lQ& EXCL.. REMOVAL S 8 EPHEM REM. m 1 4 LI -- --x--x-.." . . X J J A S O N O J F M A M J J A 0... ..O Scytosiphar *-a --,* ad*- *,J- /\o a *-8' " , J J A S O N D J F M A M J J A A.-.A 0 x---x 0 Ephememl Algoe FIG.3. Effect of herbivores and algal competitors on the occurrence of Petalonia and Scytosiphon in the mid intertidal zone of Canoe Beach Cove, Nahant, Massachusetts. See Fig. 2 legend and text for details. Menge 1975, B. Menge 1976). One of these experiments was specifically designed to test the effects of Littorina on Petalonia, Scytosiphon, and their ralfsioid crusts; additional information on these interactions was obtained as a by-product of other experiments. Each experiment consisted of at least the following four treatments: (1) an unmanipulated control (no cage or roof); (2) a roof control (tests for shading effects of the mesh; herbivores have normal access to the area underneath the roof); (3) a Littorina littorea enclosure (four periwinkles, usually 1.2-2.0 cm in length enclosed in a cage; this biomass is within the range normally occurring in nonexperimental areas); and (4) herbivorous gastropod exclusion. In all treatments, herbivores such as isopods or amphipods could and did enter the cage. Various other treatments were added as deemed necessary. For example, an herbivore exclosure from which the brown alga Fucus or ephemeral algae was removed was used to separate effects of herbivores from effects of potential algal competitors on Petalonia or Scytosiphon. Experiments were established at two sites. One set was in the high intertidal zone (+ 1.87 m) at Grindstone Neck, on flat, horizontal granite with a cover of ephemeral algae but no algal crusts (Fig. 2). The other was on flat, horizontal substratum in the mid zone (+0.4 m) at Canoe Beach Cove, with no upright algae but with traces of the red crust Hildenbrandia rubra (Fig. 3). The remainder of the primary substratum in this experiment was bare, i.e., lacked macroscopic plants or animals. Both experiments were on emergent substrata, i.e., exposed to air at low tide (as opposed to being in tide pools). Field herbivore exclusions: results.-The results in Fig. 2 support the hypothesis that grazing by L. littorea, not inability to withstand summertime conditions, caused the absence of Petalonia blades and Scytosiphon tubes during the summer. In the unmanipulated control and the roof control (Fig. 2A, B), with periwinkle grazing in the spring, summer, and fall, Petalonia and Scytosiphon appeared only during the winter (December-February). Where L. littorea was excluded (Fig. 2D, E), Petalonia also appeared during the "wrong" time of the year, i.e., in the summer (July-August 1974), and Scytosiphon also colonized out of season, i.e., in the spring and summer (May-July 1975). Where L. littorea was enclosed (Fig. 2C), neither Petalonia nor Scytosiphon nor any other heteromorphic uprights ever appeared even in the winter. Ralfsioid crusts were not observed in any of these treatments, but were present in the general area. The abundances of Petalonia and Scytosiphon in the herbivore removal experiments were inversely related to the abundances of various ephemeral algae, suggesting that Petalonia and Scytosiphon may compete with other ephemeral algae (Fig. 2D, E) when herbivores are absent. The experiments in Fig. 3 tested this hypothesis. This cage set was in the mid intertidal zone where L. littorea is more abundant than in the June 1980 HERBIVORY A N D ALGAL LIFE HISTORIES high zone experiments of Fig. 2. Here again, Petalonia and Scytosiphon occurred in the control and roof only during the wintertime when the snails are usually less active (Fig. 3A, B). Where L. littorea was enclosed in cages (Fig. 3C), it prevented most algae (including Petalonia and Scytosiphon) from becoming established, even in the winter. L. littorea usually retreat to crevices during the winter and seldom (but occasionally) forage. Snails enclosed in cages do feed, but at reduced rates as compared with the summer. Thus caged snails can evidently prevent even wintertime occurrence of most algae, unless very dense settlement of algae (swamping) occurs. Where herbivores were excluded (Fig. 3D, E , F), algae were more abundant. The particular kind of alga that comes in is probably a function of the plants which are available to colonize and of competitive interactions between those plants which do settle (J. Lubchenco Menge 1975, Lubchenco and B. Menge 1978, J. Lubchenco, personal observation). In all three exclosures (Fig. 3D, E, F) Petalonia blades and sometimes Scytosiphon tubes appeared in July, the "wrong" time of year for blades and tubes. Where Fucus and ephemeral algae were continually removed, Petalonia and Scytosiplzon continually colonized (Fig. 3F). In herbivore exclusion cages where ephemeral species but not Fucus were removed, Fucus took over the cage (Fig. 3E) and neither Petalonia nor Scytosiphon occupied primary space. (EAperiments on competitive interactions between Fucus and various ephemeral species will be reported elsewhere.) These results indicate that it is physiologically possible for Petalonia blades and Scytosiphon tubes to exist during the summer months. These plants appear to be normal and healthy, judging by their color and size. Thus warmer temperatures or longer daylengths neither kill nor stunt them. Similar results have occurred in a number of other experiments designed to investigate other algae. Upright forms of Petalonia and Scytosiphon appeared out of season in 33% of 15 herbivore exclusion cages where free space was available (i.e., unutilized by other upright algae or animals; out of a total of 53 herbivore exclusion cages in place for 1-5 yr at the four study sites). Moreover, upright Petalonia and Scytosiphon can sometimes be found in nonexperimental (uncaged) areas at the "wrong" time of year. In the summer these plants were generally in the mid and low zones, both in tide pools and on emergent substrata. J.L. has observed this only a few times in 5 yr, at more wave-exposed areas, e.g., East Point and Pemaquid Point, where herbivores such as littorinids are less abundant and/or less effective, and waves remove potential competitors more frequently. Other investigators have also reported Petalonia and Scytosiphon occurring during summer and fall months in New England at exposed sites (Lamb and Zimmerman 1964, Mathieson and 68 1 Fralich 1972, 1973, M. H. Zimmerman,personal communication). Thus the general pattern of Petalonia and Scytosiphon upright occurrence in the field corresponds to laboratory culturing results: uprights occur during the winter. The occurrence of a few uprights out of season (either in herbivore exclusion cages or exposed sites where herbivores are rare or ineffective) may be a result of the small variation in plant response to photoperiod and temperature reported by Wynne (1969; see above). In similar herbivore exclusion and sometimes in competitor removal cages, the other heteromorphic species also appeared out of season. Uprights of Ulothrix, Bangia, and Porphyra were all observed during June, July, and August when they are normally absent (Fig. 1). Oregon studies Description of the sites and species studied.-The Oregon studies were performed at two sites near Coos Bay: South Cove of Cape Arago and Sunset Bay. The study plots at each site were above the mean high tide level on the wave-exposed sandstone rocks of the outer coast. (The level of the study areas corresponds to "Zone 1," the uppermost intertidal zone, in the scheme of Ricketts et al. 1969.) At the tidal level of these study areas there are wet and dry seasons which result from seasonally changing weather conditions and tidal cycles. In the wet season (late autumn, winter, and early spring) air temperatures are cooler, precipitation is greater, tidal levels are higher during the daylight hours, and the rocks receive more spray and wash from the waves generated by winter storms. During this season the high rocks are almost continually wet, even at low tide. In the dry season (late spring, summer, early fall) the high intertidal rocks often dry out at low tide; this pattern is modified in some years by cool, wet fogs in the late spring and early summer (Cubit 1975). In the areas of the study plots, the most abundant herbivores in terms of biomass per unit area were the acmaeid limpets, nearly all of which were Collisella (=Acmaea) digitalis. Chironomid flies, gammarid amphipods, and littorinid snails were also occasionally abundant in certain areas. The abundance of algae at these sites varied with the seasons. In the winter wet season there is a bloom of microalgae (diatoms and blue-greens) and macroalgae. Nearly all of the macroalgae comprising this bloom are in the genera treated in this paper: Bangia, Porphyra, and Urospora. Most of these algae disappear from the high intertidal zone during the drier conditions of summer. These plants and their life cycles are described below. (Bangia fuscopurpurea has been described in the previous section.) All of these species have heteromorphic life cycles. 682 JANE LUBCHENCO AND JOHN CUBIT 1) Porphyra perforata J. Ag., P. pseudolanceolata Krishnamurthy , and P. schizophylla Hollenberg (Rhodophyta: Bangiaceae). The general features of the life histories of these species of Porphyra are similar to those described above for this genus in New England. Most of the Porphyra plants in the Oregon study areas were <5 cm wide and <10 cm long. Size and shape vary somewhat among the species. For these species, alternations of generations between the upright stages and the "Conchocelis" stages may be obligatory, since no other types of reproduction have yet been reported (Mumford 1975, Conway et al. 1976). 2) Urospora perlicilliformis (Roth) Aresch. (Chlorophyta: Acrosiphoniaceae). The upright, macroscopic plants are filamentous, reaching a maximum size of 30-40 mm long and 0.06 mm in diameter. Reproduction in the macroscopic stage is by at least four different reported methods: (1) fragmentation, (2) asexual production of quadriflagellate zoospores, (3) asexual production of akinetes (nonmotile spores), and (4) sexual reproduction. In the last, the zygote develops into a free-living "Codiolurn" stage that penetrates the encrusting red alga Petrocelis (Abbott and Hollenberg 1976). Chapman and Chapman (1976) also report "Gomontia" as the alternate stage of Urospora. Experiments and observations.-To investigate seasonal variations in the effects of limpet grazing on populations of high intertidal algae, sets of limpet exclosures and controls (4-5 of each per set) were established at 3-4 mo intervals staggered over a period of 2.5 yr. A total of 46 exclosures and 45 controls was set out in this series of experiments. Each set of study plots was randomly selected from a much larger group of plots that had been chosen earlier for their relative similarity. Within each set of study plots, exclosures and controls were again designated randomly. The size and shape of a plot was determined by its topography: the average area of the study plots was 1651 cm2. There was no significant difference between the mean areas of the control and exclosure plots (P > .4). Cageless methods were used to exclude the limpets since in this high intertidal habitat cages themselves would be expected to reduce the physical stresses of desiccation, insolation, and high temperatures, as well as reduce grazing. A continuous strip of copper paint kept the limpets out of the exclosure plots; a discontinuous strip of the paint was applied around controls. This paint was effective only in the exclusion of limpets; littorinid snails and arthropod grazers were not prevented from entering the exclosures. Further details of this exclosure technique are reported in Cubit (1975). Algal abundance was measured as the percent coverage of each genus and was estimated by projecting a stratified-random array of points onto color trans- Ecology, Vol. 61, No. 3 parencies of the plots, a method similar to that of Connell(1970). In the cases where the filamentous Bangia and Urospora grew so closely intermingled that they could not be separated their coverage was measured as a Bangia-Urospora mixture. The relative abundances of these algae are reported here only for the first 6 mo following the establishment of each study plot. In the longer term the succession of barnacles, perennial algae, and other organisms altered the substrate and other growing conditions within the exclosures so that for the purposes of this paper they were no longer comparable to the controls. At all times of year, including summer, there was an immediate increase in algal cover following the exclusion of limpets. Urospora and Bangia were generally the first macroalgae to appear in the exclosures, often in mixed stands, and were followed by Porphyra and the isomorphic green alga Ulva. The percent coverage data for the exclosures and controls are summarized by month for the 2.5-yr period in Table 1. The number of plots in which each alga was present is also given as a measure of the extent to which the alga occurred over the study areas. In summer the algal covers within the exclosures were much greater than those in the controls for the same months and were comparable to the natural algal blooms of the winter months. From March through October Bangia, Urospora, and Porphyra formed higher percent covers and occurred in more plots of the exclosures than in the controls. With the possible exception of Porphyra, these genera were continually present throughout the year in the exclosures as compared to being ephemerally present in the controls. September was the only month in which no Porphyra was recorded in an exclosure. The probable explanation for this is that a total of only six exclosures was censused in this month, and that these six exclosures were probably too new for Porphyra to have established. Three other, older exclosures not censused in September, but censused shortly before and after (28, 29 August 1972 and 5 October 1972), contained Porphyra on both dates, suggesting that this alga was present in September as well. The months of lowest abundance of algae in the controls were April and October. In April none of the upright morphs was found in the 13 controls censused, while Bangia and Urospora were found in 12 and 11 of the 13 exclosures, forming up to 26 and 23% covers, respectively, with both averaging 3% overall in pure stands. In mixed stands, Bangia and Urospora ranged up to 51% cover with an average over all the exclosures of 15% cover. Porphyra was more rare, but occurred in five of the 14 plots. Its percent cover averaged over all exclosure plots was 2% and up to 1% in individual plots. In October Urospora was the only alga of this group found in the controls: it occurred in trace amounts in June 1980 HERBIVORY AND ALGAL LIFE HISTORIES 683 TABLE1. Monthly comparisons of algal covers in limpet exclosures and controls on the Oregon coast. Treatments were set up over a 2.5-yr period and monitored for 6 mo. Percent covers shown are overall means for each month followed by the minima and maxima, respectively, in parentheses. Percent covers of pure and mixed stands of Bangia and Urospora are presented separately (Bangia, Urospora, and B-U mix). The figures for the number of plots in which an alga occurred include plots in which there were only trace amounts (<0.5% cover) of the alga. These occurrence data for Bangia and Urospora are totals for all the plots in which the alga was present regardless of its being in mixed or pure stands. See text for further explanation. Exclosures N Bangia Urospora B-U mix Controls Porphyra Total N Bangia Urospora B- U mix Porphyra Total Jan. % cover No. plots with this alga Feb. % cover No. plots with this alga Mar. % cover No. plots with this alga Apr. % cover No. plots with this alga May % cover No. plots with this alga June % cover No. plots with this alga July % cover No. plots with this alga Aug. % cover No. plots with this alga Sept. % cover No. plots with this alga Oct. % cover No. plots with this alga Nov. % cover No. plots with this alga Dec. % cover No. plots with this alga two of the 20 controls. In the exclosures, however, Urospora and Bangia were abundant in mixed stands, occurring together in 12 of the 21 exclosures, averaging 25% cover overall and ranging up to 97% cover in individual exclosures. Porphyra was also present in the exclosures in October: it was present in six of the 21 exclosures, averaging 2% cover overall, and ranging up to 25% cover. The extent and species composition of the algal cov- 684 JANE LUBCHENCO AND JOHN CUBIT ers varied considerably among the exclosures; observations of colonization patterns within the exclosures suggested that this variation resulted from competition among the algal species (as in the New England studies) as well as from grazing by littorinid snails and other small herbivores which were not excluded in these experiments. For instance, those exclosures with a higher degree of structural complexity (crevices, holes, barnacles, etc.) harbored higher densities of nonlimpet grazers and developed lower percent covers of algae. This effect varied from plot to plot according to the amount of shelter there. Observations that Porphyra was more common in those portions of the exclosures where light grazing by littorinid snails and other herbivores had reduced the densities of filamentous species of algae suggested that the abundance of Porphyra was negatively affected by competition, but favored by some grazing. The results of the experiments presented here indicate that herbivory plays a substantial role in controlling the seasonal abundance of the upright thalli of certain common annual and ephemeral algae of the intertidal coasts of New England and Oregon. At the high algal densities that occurred within the herbivore exclosures, competition apparently also affected the abundances of some species. In New England, the upright thalli of Petalonia, Scytosiphon, Ulothrix, Bangia, and Porphyra are normally winter annuals, but in the experiments where they were protected both from herbivores and competitors, they were present in other seasons of the year. In the field experiments protecting them only from herbivores, these algae still occurred out of season, but to a lesser extent than when competitors were also removed. In the laboratory experiments, the upright thalli of these algae are all highly preferred food of the common grazers (Lubchenco 1978). Thus grazing is probably important in ultimately determining the seasonal abundance of the upright morphs. On the high intertidal rocks in Oregon, the upright morphs of Bangia, Porphyra, and Urospora are also primarily winter annuals. Although individuals of these species may be found at other times of year at lower intertidal levels (and occasionally at higher levels) the bulk of the populations in the high intertidal zone occur during the winter (Table 1 "controls"). In the protection of the limpet exclosures these algae were present and common throughout the year. Densities of possibly competing species were not experimentally manipulated in the Oregon studies. However, observations of successional sequences and other growth patterns within the limpet exclosures suggest that interspecific competition also may have affected the relative abundances of these algae. Areas yet to be investigated are the demography and other aspects of the ecology of the naturally oc- Ecology, Vol. 61, No. 3 curring crustose and boring "Ralfsia," "Conchocelis," and "Codiolum" stages such as the study by Paine et al. (1979) for the crustose red alga Petrocelis middendorfJi. The crustose "Ralfsia" morphs in New England are known to be more grazer resistant than are the upright morphs (Lubchenco 1978). From our field observations we infer that the Oregon crustose morphs and all of the boring morphs are also less vulnerable to being removed by herbivores. In the course of our studies we have observed that the crustose algae in general are more abundant in, if not entirely restricted to, areas where herbivores are common and active. There is indication from other studies that the establishment of at least some species of crustose algae may require the removal of their upright competitors by herbivores (Vine 1974, Adey and Vassar 1975, Wanders 1977). There are few field studies applicable to the algae which penetrate or burrow into crustose algae, shells, and wood; however, we presume that within such substrata the boring morphs are sufficiently protected from herbivores that their survival exceeds that of the upright morphs through seasons of, and in habitats of, greater exposure to herbivory (Mumford 1973). (Some of these boring morphs may live within the shells of the grazers themselves.) As with the crustose forms, herbivory may also be necessary to maintain the boring morphs. If the exteriors of the substrata occupied by these algae were to become covered with other algae, the algae below the substrate could be smothered or shaded out. The preceding experiments and observations indicate that increases of grazing intensity in summer can prevent the year-round survival of the upright stages of the algae we studied. Thus we suggest that a primary adaptive value of the nonupright crustose and boring stages of these species is both in their ability to persist through times when the uprights are removed by grazers and to exist in areas of persistently heavy grazing where the upright stages themselves cannot survive. We suggest, however, that under conditions of light grazing the upright stages are competitively superior and have the additional selective advantages of rapid establishment, fast growth to reproductive maturity, and subsequent production of large numbers of propagules. We suggest that for plants such as these in mid to high intertidal habitats, a single type of plant cannot serve both functions well, because the adaptations which confer protection from herbivores are mutually exclusive with those required for competitive superiority, rapid colonization, and high rates of reproduction as discussed below. If this is correct, in habitats of spatially and temporarily heterogeneous patterns of grazing, a heteromorphic alga will be more successful than one which is isomorphic. Among the adaptations of the nonupright stages which may provide protection from herbivores are the following: (1) In the crustose forms muth of the thallus June 1980 HERBIVORY AND ALGAL LIFE HISTORIES 685 TABLE 2. Predictions of the predominant life history for mid to high intertidal ephemeral algae under different grazing regimes, according to the definitions and constraints indicated in the footnotes. If grazing pressure* is: a. Light 1. Constant and b. Heavy a . Predictable$ 2. Variable? and b. Unpredictable Then we predict: Isomorphology: competitively superior morphs (uprights) predominate Isomorphology: grazer-resistant morphs (e.g. crusts and borers) predominate Heteromorphology: alternation of production and predominance of morphs (e.g. seasonally) Heteromorphology: continuous production, but not survival, of both morphs * T h e probability that a given individual alga will b e removed b y herbivory In a given period of time. Grazing pressure fluctuates with the condition that periods of high and low grazing pressure exceed generation tlrnes of nonupright and upright rnorphs, respectively. $ Fluctuations in grazing pressure can b e forecast (e g., by correlat~onswith time or other cues from the environment). 7 adheres tightly to the substratum; thus the whole thallus is not lost if an herbivore removes a small portion at the base. (2) The thallus is tough, formed of many layers of cells compacted together, and thus may be more difficult to graze. (3) Some Ralfsia are reported to contain tannins (Conover and Sieburth 1966) which may be herbivore deterrents. (4) The burrowing forms are presumably protected from herbivores by being within other crustose algae or hard substrata such as shells and wood. Among the adaptations of the uprights that might contribute to higher growth rates at the expense of resistance to herbivory are the following: (1) Since most of the surface of an upright thallus neither adheres to the substratum nor is buried in it, and the thallus is either filamentous or only a few cells thick, the ratio of exposed surface to internal volume of the plant is greater than in the nonupright forms. This allows potentially higher growth rates through more rapid assimilation of nutrients (Odum et al. 1958, Fogg 1965) and a higher ratio of photosynthetic area per unit biomass. (2) Upright forms presumably allocate less energy and material for attaching themselves to the substratum or burrowing through it. (3) With small points of attachment, the uprights require less space per unit biomass than the crustose forms, an adaptation that is important in space-limited habitats of the intertidal zone. (4) The uprights are probably not as restricted in substrate requirements as are the burrowing forms. As noted earlier it has been suggested that the crustose and boring stages of heteromorphic algae serve as perennating phases through the seasons when the upright stages are unable to tolerate the physical stresses of the habitat (Wynne 1969, Conway et al. 1976). Low surface-to-volume ratios and living within perforations of the substrate probably do render these nonupright forms more resistant to desiccation and the damaging effects of insolation and high temperatures. We agree that the nonupright stages serve as perennating phases, but suggest that grazing and perhaps competition should be considered as important factors preventing the upright stages of these algae from being perennial. Vadas (1979) has suggested that heteromorphic al- gae may be under bimodal seiection pressures, simultaneously evolving toward opposing ends of the r and K continuum of selection. However, if our arguments above are correct, the upright stages exhibit both r and K characteristics: rapid growth, early maturity, and high reproductive output (r) as well as competitive superiority (K), and the bimodality of selection exists between this combination and the ability to withstand grazing. In the following discussion we define the term grazing pressure as the probability with which a given individual alga will be removed by herbivory in a given period of time. If the preceding explanations are correct we would predict that the relative proportions of heteromorphic and isomorphic algae should vary from habitat to habitat according to the seasonal fluctuations of grazing in those places. In areas where grazing pressure does not fluctuate, we would expect isomorphic algae (either upright or nonupright) to predominate, the type of morph being determined by grazing intensity (Table 2). If grazing pressure were constantly low, the upright morphs should outcompete the nonupright morphs (Table 2, la). If grazing pressure were constantly high, the uprights should be removed and the nonuprights survive in their place (Table 2, lb). Under such conditions, algae with obligate alternations of heteromorphic generations should eventually disappear as one morph or the other is eliminated by competition or grazing. Those algae with alternations of heteromorphic generations that are not obligate may have one morph survive, but it should be at a lower relative fitness than similar, but isomorphic, species in which no reproductive efforts are wasted on producing the morphs which do poorly in these conditions. In contrast, where grazing pressure does fluctuate from season to season, conditions should alternately favor upright, then nonupright morphs, resulting in selection for seasonal alternation of these morphs (Table 2, 2a). Greater fitness should accrue to those heteromorphic algae which allocate their resources into the production of nonuprights and uprights in synchrony with the grazing changes. Just prior to the onset of the seasons of increased grazing it should be to the advantage of an upright alga to convert its re- 686 JANE LUBCHENCO AND JOHN CUBIT sources to the grazer-resistant morph rather than have these resources consumed by herbivores. Similarly, selection should favor those algae concentrating their production of uprights in the seasons of reduced herbivory (Table 2, 2a). Finally, if grazing pressure fluctuates in an unpredictable manner, both morphs should be present continually (Table 2, 2b). Each morph will be favored at some time, but prediction of precisely when is not possible. Thus each plant should be most fit by producing offspring of both morphs. According to this scheme, the New England and Oregon studies reported above are examples of Table 2, 2a in which uprights are favored during the winter months and nonuprights during summer months. In our field studies, decreases in grazing pressure occur in winter and increases occur in summer. Numerous factors in the physical environment are correlated with the grazing changes and could be used by an alga as cues to change from one morph to another. These factors include temperature, insolation, photoperiod, desiccation, wave force, and salinity. Laboratory culturing experiments have demonstrated that the switch from upright to nonupright morphs or vice versa is under photoperiodic or temperature control or both for Petalonia, Scytosiphon, Bangia, and Porphyra (Dring 1967, Wynne 1969, Bixon and Richardson 1970, Sommerfeld and Nichols 1973, Roeleveld et al. 1974). In the Oregon study areas species of Porphyra were observed to liberate spores during the first series of daytime low tides and warm weather in the spring. For the algae discussed here, it makes little difference which cues are used for timing, providing the cues are closely correlated with the seasonal increases and decreases in the probabilities of being consumed by herbivores. The strength of selective pressure to respond to these cues should depend on the closeness of the correlation. Conceivably there are environments in which the seasonal variations in grazing pressure are the reverse of those in our study areas; in such areas we would expect opposite responses to the same cues, all other factors being equal. The mechanisms which we suspect cause the variations of grazing pressure in New England and Oregon might follow other seasonal patterns on other coasts. In New England the winter reduction in grazing is apparently the result of wave action causing littorinids to decrease their grazing activities during the winter months (J. Lubchenco Menge 1975). Evidently this same phenomenon also occurs on parts of the Oregon coast where storm-generated waves decrease the densities andlor activities of littorinids (Castenholz 1961, Behrens 1974, Cubit 1975). In the particular Oregon study areas described in this paper the winter decrease in grazing pressure apparently results from a swamping of the grazing capacities of the limpet populations by increased algal productivity rather than a reduction of the grazing activities of the limpets (Cubit 1975). In other habitats factors such as seasonal removal of her- Ecology, Vol. 61, No. 3 bivores by predators, or seasonal influx of algal drift may also operate to reduce grazing at other times of year and change the selective regime for the timing of production of the various morphs of the heteromorphic algae. In other words, rather than the seasonal abundance of these different morphs being dependent on the timing responses of the plants, the timing responses are probably dependent on the seasonal survival of these morphs. Our experiments do not address factors involved in the origin of heteromorphology; they demonstrate only that variation in the grazing regime may maintain this adaptation in the species investigated. The hypotheses and predictions put forth in this paper are not intended to explain the occurrence of heteromorphology in all algae. Rather, we have focused on one of the mechanisms that may be involved in selection for heteromorphology of common species that have annual or ephemeral upright thalli in the mid and higher littoral zones. Since the morphologies of stages and the patterns of life cycles in other heteromorphic algae differ from those we have studied, the selective mechanisms probably also differ. Moreover, the hypotheses presented in this paper are subject to further testing, particularly regarding the ecology of the nonupright stages. For example, more information is needed on (1) the demography and phenology of the crustose and boring stages, (2) the relative competitive abilities of uprights vs. nonuprights, and (3) effects of other factors, e.g., seasonal burial and scour by sand which might act similarly or in addition to grazing in selecting for heteromorphology. We thank the following people for field assistance or comments on versions of this manuscript: L. Ashkenas, R. W. Day, P. K. Dayton, S. D. Gaines, M. E. Hay, J. A. Kilar, E. G. Leigh, B. A. Menge, T. F. Mumford, Jr., J. N. Norris, R. T. Paine, W. P. Sousa, J. A. West, S. D. Williams, and two anonymous reviewers. J. Lubchenco is grateful to N . W. Riser for use of Northeastern University's Marine Science Institute, Nahant, Massachusetts. This paper is contribution 51 from that laboratory. J. Lubchenco's research was supported by National Science Foundation Grants GA-40003 to J. Lubchenco and GA-35617 and DES72-01578-A01 to B. Menge. J. Cubit thanks P. 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Stable URL: http://links.jstor.org/sici?sici=0012-9615%28197623%2946%3A4%3C355%3AOOTNER%3E2.0.CO%3B2-R Uptake of P32 and Primary Productivity in Marine Benthic Algae Eugene P. Odum; Edward J. Kuenzler; Marion Xavier Blunt Limnology and Oceanography, Vol. 3, No. 3. (Jul., 1958), pp. 340-345. Stable URL: http://links.jstor.org/sici?sici=0024-3590%28195807%293%3A3%3C340%3AUOAPPI%3E2.0.CO%3B2-Z The Biology of Brown Algae on the Atlantic Coast of Virginia. II. Petalonia fascia and Scytosiphon lomentaria Russell G. Rhodes; Mary U. Connell Chesapeake Science, Vol. 14, No. 3. (Sep., 1973), pp. 211-215. Stable URL: http://links.jstor.org/sici?sici=0009-3262%28197309%2914%3A3%3C211%3ATBOBAO%3E2.0.CO%3B2-G Developmental and Cytological Studies of Bangia fuscopurpurea in Culture Milton R. Sommerfeld; H. Wayne Nichols American Journal of Botany, Vol. 57, No. 6. (Jul., 1970), pp. 640-648. Stable URL: http://links.jstor.org/sici?sici=0002-9122%28197007%2957%3A6%3C640%3ADACSOB%3E2.0.CO%3B2-M