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Chapter 3: Cells • Plasma membrane: structure • Plasma membrane: transport • Resting membrane potential • Cell-environment interactions • Cytoplasm • Nucleus • Cell growth & reproduction • Extracellular materials & developmental aspects Department of Health, Nutrition, and Exercise Sciences WCR Cell cycle From one cell division to the next Interphase Mitotic phase G1 checkpoint (restriction point) S Growth and DNA synthesis G1 Growth M G2 Growth and final preparations for division G2 checkpoint Copyright © 2010 Pearson Education, Inc. Figure 3.31 Video Molecular Visions of DNA Narrated version at Walter & Eliza Hall Institute site. Animation of DNA replication and phase contrast video of cell division. http://www.wehi.edu.au/education/wehitv Backup: Parent site: Choose Molecular Visions of DNA. Department of Health, Nutrition, and Exercise Sciences WCR DNA Replication • DNA helices unwind from nucleosomes • Each nucleotide strand serves as a template for building a new complementary strand • DNA polymerase makes the complementary strands • End result: two DNA molecules formed from the original Copyright © 2010 Pearson Education, Inc. Chromosome Free nucleotides DNA polymerase Old strand acts as a template for synthesis of new strand Leading strand Old DNA Helicase unwinds the double helix and exposes the bases Replication fork Adenine Thymine Cytosine Guanine DNA polymerase Old (template) strand PLAY Copyright © 2010 Pearson Education, Inc. Two new strands (leading and lagging) synthesized in opposite directions Lagging strand Animation: DNA Replication Figure 3.32 Cell Division • Mitotic (M) phase of cell cycle • Essential for body growth and tissue repair • Does not occur in most mature neurons, skeletal and cardiac myocytes • Includes two distinct events • Mitosis—nuclear division • Cytokinesis—division of cytoplasm by cleavage furrow PLAY Copyright © 2010 Pearson Education, Inc. Animation: Mitosis Protein Synthesis • DNA = master blueprint for protein synthesis • Gene = segment of DNA with blueprint for one polypeptide • Polypeptide = polymer of amino acids; protein = one or more polypeptides • Each set of 3 nucleotide bases (triplet or codon) specifies (codes for) an amino acid in the polypeptide PLAY Animation: DNA and RNA Copyright © 2010 Pearson Education, Inc. Nuclear envelope Transcription RNA Processing DNA Pre-mRNA mRNA Translation Nuclear pores Ribosome Polypeptide Copyright © 2010 Pearson Education, Inc. Figure 3.34 Three “classical” types of RNA • Messenger RNA (mRNA) • Carries instructions for building a polypeptide, from gene in DNA to ribosomes in cytoplasm • Ribosomal RNA (rRNA) • A structural component of ribosomes that, along with tRNA, helps translate message from mRNA • Transfer RNAs (tRNAs) • Bind to amino acids and pair with bases of codons of mRNA at ribosome to begin process of protein synthesis Copyright © 2010 Pearson Education, Inc. NYTimes Feb 7 2011 Fire & Mello: Nobel Prize, 2006, for discovery of RNA interference. “Non-classical” types of RNA: regulatory • Micro RNAs (miRNAs) • Single-stranded, 21-33 nt, partly complementary to an mRNA, usually down-regulates expression of mRNA’s protein product • Small interfering RNAs (siRNAs) • Double-stranded, 20-25 nt, usually down-regulates expression of complementary mRNA’s protein product; lab-made versions being tested as treatments for AIDS, AMD • More types & roles being discovered Copyright © 2010 Pearson Education, Inc. Videos Central Dogma, Part 1: Transcription (narrated version at WEHI.edu.au) Central Dogma, Part 2: Translation (narrated version at WEHI.edu.au) Hemoglobin & Sickle Cell Anemia If there’s time: No narration. Notes: Hb is a tetramer. Bright blue O2. Hb dark red; HbO2 bright red. HbS has one wrong aa (green). HbS sticks together, forming intracellular rods. http://www.wehi.edu.au/education/wehitv Backup: Parent site: Choose Central Dogma Part 1, then Central Dogma Part 2. Select Haemoglobin & Sickle Cell Anemia if time allows. Department of Health, Nutrition, and Exercise Sciences WCR Transcription • Making mRNA from a gene on DNA • mRNA complementary to corresponding DNA • RNA polymerase • Enzyme overseeing mRNA synthesis • Unwinds DNA template, adds complementary RNA nucleotides, joins them together • mRNA detaches from DNA template, is further processed by enzymes, exits nucleus & enter cytoplasm through nuclear pore • Transcription factor • Protein that binds to regulatory DNA near gene, usually enhances transcription of gene Copyright © 2010 Pearson Education, Inc. RNA polymerase Coding strand DNA Promoter region Template strand Termination signal 1 Initiation: With the help of transcription factors, RNA polymerase binds to the promoter, pries apart the two DNA strands, and initiates mRNA synthesis at the start point on the template strand. mRNA Template strand Coding strand of DNA 2 Elongation: As the RNA polymerase moves along the template Rewinding of DNA strand, elongating the mRNA transcript one base at a time, it unwinds the DNA double helix before it and rewinds the double helix behind it. mRNA transcript RNA nucleotides Direction of transcription mRNA DNA-RNA hybrid region Template strand RNA polymerase 3 Termination: mRNA synthesis ends when the termination signal is reached. RNA polymerase and the completed mRNA transcript are released. Unwinding of DNA The DNA-RNA hybrid: At any given moment, 16–18 base pairs of DNA are unwound and the most recently made RNA is still bound to DNA. This small region is called the DNA-RNA hybrid. Completed mRNA transcript RNA polymerase Copyright © 2010 Pearson Education, Inc. Figure 3.35 Translation • Making a polypeptide (amino acid chain, usually a protein) using mRNA “instructions” • Involves mRNAs, tRNAs, rRNAs • Small ribosomal subunit, then large, attach to mRNA • tRNAs and their AAs, complementary to 1st & 2nd codons on mRNA, attach to mRNA-ribosome complex • Ribosome attaches the 2 AAs to each other, then moves forward one codon on mRNA, releasing first tRNA • Process repeats until reach stop codon – now polypeptide is complete Copyright © 2010 Pearson Education, Inc. Nucleus RNA polymerase mRNA Leu Template strand of DNA 1 After mRNA synthesis in the nucleus, mRNA leaves the nucleus and attaches to a ribosome. Energized by ATP, the correct amino acid is attached to each species of tRNA by aminoacyl-tRNA synthetase enzyme. Amino acid Nuclear pore tRNA Nuclear membrane G A A 2 Translation begins as incoming aminoacyl-tRNA recognizes the complementary codon calling for it at the A site on the ribosome. It hydrogen-bonds to the codon via its anticodon. Released mRNA Aminoacyl-tRNA synthetase Leu 3 As the ribosome moves along the mRNA, and each codon is read in sequence, a new amino acid is added to the growing protein chain and the tRNA in the A site is translocated to the P site. Ile tRNA “head” bearing anticodon Pro 4 Once its amino acid is released from the P site, tRNA is ratcheted to the E site and then released to reenter the cytoplasmic pool, ready to be recharged with a new amino acid. The polypeptide is released when the stop codon is read. E site P site G G C A site A U A C C G C U U Codon 15 Codon 17 Codon 16 Large ribosomal subunit Small ribosomal subunit Direction of Portion of mRNA ribosome advance already translated Copyright © 2010 Pearson Education, Inc. Figure 3.37 Role of Rough ER & Golgi in protein synthesis • mRNA–ribosome complex finds and attaches to rough ER • Forming protein enters ER • Protein is enclosed in a vesicle for transport to Golgi apparatus • Sugar groups may be added to protein (glycosylation) in RER and/or in Golgi • Vesicles from Golgi carry finished proteins to cell surface for incorporation into membrane or exocytosis Copyright © 2010 Pearson Education, Inc. 1 The mRNA-ribosome complex is directed to the rough ER by the SRP. There the SRP binds to a receptor site. ER signal sequence 2 Once attached to the ER, the SRP is released and the growing polypeptide snakes through the ER membrane pore into the cisterna. 3 The signal sequence is clipped off by an enzyme. As protein synthesis continues, sugar groups may be added to the protein. Ribosome mRNA Signal Signal recognition sequence particle Receptor site removed (SRP) Growing polypeptide 4 In this example, the completed protein is released from the ribosome and folds into its 3-D conformation, a process aided by molecular chaperones. Sugar group 5 The protein is enclosed within a protein (coatomer)-coated transport vesicle. The transport vesicles make their way to the Golgi apparatus, where further processing of the proteins occurs (see Figure 3.19). Released protein Rough ER cisterna Cytoplasm Copyright © 2010 Pearson Education, Inc. Transport vesicle pinching off Coatomer-coated transport vesicle Figure 3.39 Inner Life of a Cell • Animation showing various aspects of cell function including extracellular outer & inner membrane protein interactions, cytoskeleton, translation, vesicular transport • Leukocyte = WBC; endothelial cell = cell lining a blood vessel • Leukocyte extravasation = movement of leukocyte from blood into surrounding tissue, as occurs at site of inflammation • Leukocyte is below & endothelial cell above, as if leukocyte is rolling along “roof” of blood vessel • High res animation • Lower res, clip w/ music, other animations College or Department name here Sentinel node biopsy is a technique which helps determine if a cancer has spread (metastasized), or is contained locally. When a cancer has been detected, often the next step is to find the lymph node closest to the tumor site and retrieve it for analysis. The concept of the "sentinel" node, or the first node to drain the area of the cancer, allows a more accurate staging of the cancer, and leaves unaffected nodes behind to continue the important job of draining fluids. NYT ©2009. The procedure involves the injection of a dye (sometimes mildly radioactive) to pinpoint the lymph node which is closest to the cancer site. Sentinel node biopsy is used to stage many kinds of cancer, including lung and skin (melanoma). NYT ©2009. KAAP NYTimes Feb 8 2011 Axillary Dissection vs No Axillary Dissection in Women With Invasive Breast Cancer and Sentinel Node Metastasis: A Randomized Clinical Trial. Guiliano et al., JAMA 305: 569-575, 2011. Context Sentinel lymph node dissection (SLND) accurately identifies nodal metastasis of early breast cancer, but it is not clear whether further nodal dissection affects survival. Objective To determine the effects of complete axillary lymph node dissection (ALND) on survival of patients with sentinel lymph node (SLN) metastasis of breast cancer. Conclusion Among patients with limited SLN metastatic breast cancer treated with breast conservation and systemic therapy, the use of SLND alone compared with ALND did not result in inferior survival. KAAP Extracellular Materials • Body fluids (interstitial fluid, blood plasma, and cerebrospinal fluid) • Cellular secretions (intestinal and gastric fluids, saliva, mucus, and serous fluids) • Extracellular matrix (abundant jellylike mesh containing proteins and polysaccharides in contact with cells) Copyright © 2010 Pearson Education, Inc. Developmental Aspects of Cells • Cells contain same DNA but are not identical • Chemical signals in embryo channel cells into specific developmental pathways by turning some genes off • Development of specific and distinctive features in cells is called cell differentiation • Elimination of excess, injured, or aged cells occurs through programmed rapid cell death (apoptosis) followed by phagocytosis Copyright © 2010 Pearson Education, Inc.