 |
Movement by Cable or Capture |
Secretion is polarized into the yeast bud so that the bud
grows in preference to the mother cell. Pruyne et al. (page
1931) report that this actin-based process is directed by actin fibers that extend into the bud, and not by the actin
patches that are clustered near the bud tip.
Most perturbations to the actin system depolarize both
patches and cables, but Pruyne et al. find that the combination of a temperature-sensitive tropomyosin 1 mutation
and a tropomyosin 2 deletion can be used to selectively rid
the cell of cables. Tropomyosin is found on, and stabilizes,
actin cables but is not present in actin patches.
Actin cables disappear just one minute after shifting
the double mutant to a restrictive temperature; another
minute later two other molecules are no longer concentrated at the bud tip. These proteins
Sec4, a secretory
vesicle GTPase, and Myo2p, an unconventional myosin V
implicated in targeted secretionbecome diffuse several
minutes before actin patches begin to delocalize.
When the mutant is shifted back to the permissive
temperature, tropomyosin-containing cables are reformed,
and Sec4p and Myo2p localization are reestablished within
one to two minutes. Repolarization of actin patches takes
15-20 min.
The tropomyosin double mutant should help identify
the yeast cell polarity marker. Of the proteins that are localized to the bud tip, only those that remain localized in
the tropomyosin mutant, and that are necessary for regeneration of polarized cables, will remain as the leading candidates.
This work and previous studies with Myo2p establish actin cable-based transport as the key event in yeast polarized secretion. Transport of mammalian melanosomes was
also thought to be an actin-dependent process. But in
mouse melanocytes, Wu et al. (page 1899) find that these
pigmented organelles also undergo rapid, bidirectional, microtubule-dependent movements between the cell center and the periphery. A myosin V isoform encoded by the
dilute locus is necessary for peripheral accumulation of
melanosomes, but it functions primarily by capturing these
organelles in the cell periphery.
The striking difference between these two papers may
reflect the different dimensions of the two cell types.
Smaller yeast cells may preferentially use actin-based
transport, whereas larger vertebrate cells use both short-range actin-based transport and longer-range microtubule-based transport.
| |
Gathering Together Unfolded Proteins |
When faced with unmanageable quantities of unfolded
proteins, bacteria and yeast make inclusion bodies. Now
Johnston et al. (page 1883) find that mammalian cells react
by actively gathering the protein together into an aggregate that the researchers name the aggresome.
Johnston et al. use a poorly folding mutant of cystic fibrosis transmembrane conductance regulator (CFTR) as
their model protein. Overproduction of the protein, or inhibition of the proteolytic activities of the proteasome,
leads to formation of the aggresome. Formation of these
stable structures requires microtubules; in the absence of
microtubules unfolded protein is found throughout the cytoplasm in roughly spherical, membrane-free particles 60- 80 nm in diameter. Aggresomes appear to be an aggregate
of these particles wrapped in bundles of filamentous material that includes the intermediate filament vimentin.
Vimentin forms a similar cage around the spindle during
mitosis, and its participation in aggresome formation may
be a byproduct of this mitotic role. The tangled and ubiquitinated protein in aggresomes is probably a potent proteasome inhibitor, as substrates of the proteasome must be
unfolded before they are destroyed. Inhibition of the proteasome may disrupt the cell cycle and lead to the vimentin phosphorylation that, in mitosis, causes it to coalesce
around the spindle.
Gathering together unfolded proteins may limit their interference with membranes and partially folded protein
intermediates. But aggresomes form around the centrosome, so they may disrupt microtubule-dependent trafficking in neurons, or cell division in other cells. Johnston
et al. suggest that aggresomes are a general response to
unfolded proteins, as they detect similar structures after
expressing the Alzheimer's disease protein presenilin-1. The relation of aggresomes to the protein aggregates
found in many neurodegenerative disorders remains to be
established.
| |
Not All Sarcoglycans Are Equal |
Of the three subcomplexes in the dystrophin-glycoprotein
complex, the function of the sarcoglycan subcomplex is the
least well described. The dystrophins link to actin and the
dystroglycans link to the dystrophins and the extracellular
matrix, so theoretically these two subcomplexes could be
sufficient to anchor muscle cells. But mutations in sarcoglycan and dystrophin genes cause similar muscular dystrophy syndromes.
Chan et al. (page 2033) take a first step in analyzing
sarcoglycans by dividing the subcomplex into a core of 
-
and 
-sarcoglycan, with 
- and then 
-sarcoglycan more
loosely associated. Only -sarcoglycan cross-links to the
/-dystrophin unit. The definition of a core complex
explains why human patients with - or -sarcoglycan
mutations show a complete loss or drastic reduction in all
sarcoglycan proteins, whereas patients with - or -sarcoglycan mutations often retain some sarcoglycan expression.
Intramolecular disulfide bonds are present in -, -, and
-sarcoglycan, and the protein sequences suggest that the
disulfides may form a structure resembling the ligand-binding pocket of growth factor receptors. Sarcoglycans
might be involved in mechanochemical signaling, but candidate ligands have not been defined.
| |
Nuclear Pore Complexes and Spindle Pole
Bodies Share a Component |
Until now we knew of only one attribute shared by the
spindle pole body (SPB) and the nuclear pore complex
(NPC) of budding yeast: they are both inserted in the nuclear envelope. Now Chial et al. (page 1789) report that
the SPB (yeast's version of the centrosome) and the NPC
both contain a protein called Ndc1p.
Mutants in ndc1 fail to insert the nascent SPB into the
nuclear envelope, but Chial et al. do not find a similar defect in NPC insertion. It is possible that the SPB insertion
defect is secondary to a specific defect in nuclear transport, but senior author Mark Winey favors an alternative.
"Our favorite model is that the two organelles share at
some level the same mechanism for membrane insertion,"
he says. The extreme version of the model, he says, is that
the two organelles could have a shared ancestry.
In support of the insertion model, Ndc1p localizes to the
periphery of NPCs and the edges of the SPB central
plaques. The localization data suggests that Ndc1p has a direct role in SPB insertion (contrary to previous assumptions), and may provide the first real handle on this process.
| |
Early Functions for Desmosomes |
Many desmosomal components are at least partially redundant, making it difficult to completely ablate desmosomal function. The surprising exception seems to have
been found in a desmoplakin knockout mouse described
by Gallicano et al. (page 2009).
Desmoplakin was thought to operate solely as a linker
to intermediate filaments, and indeed there are few if any
intermediate filaments associated with the desmosomes
in the knockout. But these desmosomes are also 10-fold
fewer in number and 2-fold smaller than in wild-type
embryos. Thus, it appears that desmoplakin is not only
important in attaching intermediate filaments to desmosomes, but also necessary for desmosome assembly or
stabilization. The loss of attachment to intermediate filaments does not by itself lead to a loss of desmosome integrity, as intact desmosomes are found in knockout mouse
cells that lack keratin networks.
The desmoplakin knockout mice successfully progress
past the implantation stage, suggesting that E-cadherin
linkages can withstand the forces inherent in forming a
blastocoel cavity. By embryonic day 6, ectoderm proliferation and elongation of the central egg cylinder begin to
fail. At this stage desmosomes are normally present only
in the extraembryonic tissues, such as the endoderm that
encases the ectoderm. This mutant endoderm must be failing either to protect or to send a signal to the ectoderm.
This failure, and the breaking apart of the surrounding endoderm in response to the stresses of ectodermal proliferation and remodeling, lead to embryonic lethality within
the next day.
| |
A Sex-specific Homeodomain Protein in Algae |
On page 1971, Kurvari et al. describe GSP1, the first homeodomain protein to be discovered in an alga, and the
first protein with sex-limited expression to be discovered
in Chlamydomonas. GSP1 was identified as a cDNA specific to Chlamydomonas gametes of the mt+ mating type
after a screen involving subtractive hybridization. The
GSP1 protein is absent in mt
mating type cells, but unlike other genes for mating type-specific proteins, the gsp1
gene is present in both mating types. The gsp1 gene is
turned off in mt gametes, directly or indirectly, by the
MID repressor. Based on expression profiles, GSP1 may
be turning on mating functions in mt+ gametes or regulating early expression patterns in the zygote.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati What's this?
