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Transcript
A molecular model of the interaction
between vitamin D binding protein-derived
macrophage activating factor (GcMAF)
and vitamin D receptor (VDR) -M1 shift
Maria Giulia Fiore, Stefano Magherini*, Gabriele
Morucci, Jacopo Junio Valerio Branca, Stefania
Pacini, Massimo Gulisano and Marco Ruggiero
Department of Experimental and Clinical Biomedical Sciences, and
Department of Experimental and Clinical Medicine, University of Firenze,
50134 Firenze, Italy
As early as 2010, in collaboration with Dr.
Nobuto Yamamoto,
we demonstrated an interconnection between
GcMAF and VDR signaling (XVIII
International AIDS conference, Vienna 2010).
We demonstrated that the responsiveness of
human monocytes to GcMAF was associated
with VDR gene polymorphisms.
GcMAF
• Is a member of the so-called vitamin D axis
since it derives from de-glycosylation of
Vitamin D-Binding Protein or Gc protein.
• In 2010 and following years, we demonstrated
that polymorphisms of the VDR gene, known
to be associated with the highest responses to
vitamin D receptor agonists, are associated
also with the highest responses to GcMAF.
• This observation raises the question of whether
there could be a molecular interaction between
GcMAF and the VDR.
• This question might appear odd at first, since
for many years it had been thought that VDR
was localized in the cytoplasm and in the
nucleus, whereas GcMAF could not cross the
plasma membrane and therefore had to be
recognized by a surface receptor, possibly a
lectin-type receptor.
• (J. Biol. Chem, 1999, 274(16), 10697-10705)
• In support for the hypothesis of a
GcMAF/VDR interaction, there is the
observation that VDR translocates to the
plasma membrane, and plasma-membrane
associated VDR is responsible for the rapid,
non-genomic, effects of vitamin D.
• Thus, in order to verify the possibility of a
molecular interaction between GcMAF and
VDR, we compared the amino acid sequences
corresponding to their respective vitamin D
binding sites.
•
•
J. Cell. Biochem. 2002, 86(1), 128-135.
Calcif. Tissue Int. 2013, 92, 151-162.
• There are 23 hydrophobic amino acids near the
amino terminus of GcMAF
• (-----MKRVLVLLLAVAFGHALERGRDY)
• and 23 amino acids near the carboxyl terminus
of the VDR
• (SFQPECSMKLTPLVLEVFGNEIS-----).
• These are the sequences that bind vitamin D.
• If these two sequence are aligned (Fig. A), it is
possible to observe not only that in both
proteins there is a long stretch (13-14) of
hydrophobic amino acids (highlighted in green
in Fig. A, upper insert), but that 4 hydrophobic
amino acids are identical (L L FG; indicated
in yellow and in green above and under the
alignment. The sequence of GcMAF is above).
• 11 amino acids have similar functional valence
(as indicated by the conventional symbols [*],
[.] and [:].
Nutrients. 2013 Jul 8;5(7):2577-89. doi: 10.3390/nu5072577
• A molecular interaction between the two
proteins can therefore be proposed (Fig. A).
• According to this model, the last 23
hydrophobic amino acids of VDR (VDR is on
the right of Fig. A), located at the inner part of
the plasma membrane (represented as a dotted
line), could interact with the first 23
hydrophobic amino acids of the GcMAF
(GcMAF is on the left of Fig. A) located at the
external part of the plasma membrane, with
vitamin D (represented in yellow) sandwiched
in between the two vitamin D-binding
proteins.
• Oleic acid, taken as an example of an
unsaturated fatty acid bound to GcMAF, could
stabilize the complex at the level of the plasma
membrane.
• In fact, both vitamin D and oleic acid are
located in a shallow cleft of the GcMAF
protein that makes them accessible to the
plasma membrane.
• Biochem. Biophys. Res. Commun. 1988,
153(3), 1019-1024.
• In addition to the mode of interaction proposed
in Fig. A, there could be also another one that
takes into consideration just this fact that Gc
protein (and therefore also GcMAF) binds
unsaturated fatty acids such as oleic acid.
• The fatty acid binding site is located between
domains II and III, that is between the
positions 304 and 387.
• When we aligned the 23 hydrophobic amino
acids of the VDR quoted above (represented in
the insert in Fig. B; also in this case, the
sequence of GcMAF is represented above that
of VDR) and the corresponding hydrophobic
amino acids of the unsaturated fatty acid
binding site of GcMAF (in particular, those in
position 356-386), we observed that there was
a significant degree of functional homology.
• In fact there are 8 amino acids with similar
functional valence in a long stretch of
hydrophobic amino acids (highlighted in blue).
• Therefore, it can be hypothesized that GcMAF
and VDR have multiple sites of interaction at
the level of the plasma membrane.
• According to this model, the presence of
vitamin D and oleic acid should facilitate the
interaction between GcMAF and VDR.
• This hypothesis is further strengthened by the
observation that activated macrophages
generate enough biologically active vitamin D
so as to be detectable in the general circulation
(Arch Biochem Biophys. 2012; 523: 95-102).
• However, the interaction between GcMAF and
VDR could also occur inside the cell.
• At variance with what previously thought,
vitamin D does not cross freely the membrane,
and the Gc protein/vitamin D complex is
endocytised through a receptor-mediated
mechanism.
• Therefore, Gc protein (and hence GcMAF) can
be found inside the cell.
• Once inside the cell, GcMAF could interact
with VDR thanks to the presence of a string of
acidic amino acids in the VDR sequence that
bind the Gal-N-Ac moiety of GcMAF, but not
to the non-deglycosylated (inactive) Gc
protein.
• In fact, inactive Gc protein with sialic acid
bound to Thr 420 cannot bind the string of
acidic amino acids in the VDR sequence.
Gal-N-Ac
• The interaction between GcMAF and VDR
explains the multiplicity of effects attributed to
GcMAF, and the variety of clinical
applications ranging from cancer to autism.
• In fact, VDR is expressed in a great number of
cell types and regulates a wide array of genes
involved in the control of the major cell
functions.
• The interaction between GcMAF and VDR
also explains the M1 shift induced by GcMAF
in macrophages.
• In fact, activation of VDR modulates the
expression of IL-1β, IL-6, TNF-α and TLRs
that in turn are responsible for a shift toward
the M1 phenotype.
• Activation of these factors leads to a
predominance of NF-κB and STAT1 that
promotes M1 macrophage polarization.
• J Clin Invest. 2012 Mar 1;122(3):787-95.
Conclusions
• GcMAF, just as many other agonists, might
have multiple receptors mediating different
biological effects.
• Here, we demonstrate that a molecular
interaction between GcMAF and VDR can be
envisaged on the basis of sequence analyses.
• This interactions helps explaining the
multifaceted biological effects of GcMAF as
well the induction of M1 shift.