Gene Networks Database
Paracentrotus lividus Genes in Development:
Metalloproteases
BP10
Function
BP10 codes for a metalloprotease which belongs to huBMP-1
related protein family.
It plays a role
in the differentiation and morphogenesis
of ectodermal lineages and
subsequent patterning of the embryo.
The BP10 protein and its mRNA are molecular markers of the presumptive ectoderm territory (Lepage et al., 1992).
Protein
BP10 protein contains seven domains:
a signal peptide, a putative action peptide,
a catalytic domain with an active center typical
of a Zn^2+ metalloprotease, an EGF-like domain
and two internal repeats similar to repeated
domains found in the C1s and C1r serine proteases
of the complement cascade.
Protein contains 597 amino acids.
it is a hydrophilic protein with an excess
of acidic (81 Asp + Glu) over basic amino acids
(63 Arg + Lys + His) and unusually high number
of methionine and cysteine residues.
N-terminal sequence has two plausible
cleavage sites with high scores, between residues
Cys 16 and Thr 17 and between Ala 19 and Ala 20.
The first site is clearly favored over the second one
and thus Thr 17 will be taken provisionally as the
first residue of the secreted protein.
Most of the cysteine residues are found in the
C-terminal half of the molecule and 8 of them are very
close to each other in a small cysteine-rich region
between residues 293 and 339. No potential N-glycosylation
site was found but there are series of 25 amino acids
containing 14 threonines grouped in five clusters of 2-3 residues
at positions 451-475.
The threonine-rich region splits the terminal
half of the protein into 2 regions which have almost exactly
the same length, each containing 4 cysteine residues at the
same positions and sharing 35 % identity. These threonine
clusters may be the site of O-glycosylations.
The C-terminal end of the BP10 protein is thus made up of two homologous repeats
of the same domain, arranged in tandem. And there's also
a basic stretch RKKRKA at positions 88-93,
whose sequence is reminiscent of those
present in some precursors recognized by intracellular
processing enzymes with a trypsin-like specificity (Bentley et al., 1986).
A 200 amino acid domain of the BP10 protein, beginning
around position 90 and extending to about residue 295,
is homologous to a whole small digestive protease of 22 * 10^3,
isolated from the crayfish (Astacus), which is a classical
zinc-dependent metalloenzyme (Titani et al., 1987; Stocker et al., 1988).
The overall homology score is 40 % in a 200 amino acid overlap.
A sequence homologous to this domain was also found in the
human protein BMP-1. 42 % of the 200 amino acid residues of the BP10
and BMP-1 domains are identical. The positions of the four cysteines
of the Astacus protease are conserved in the BP10 and BMP-1, suggesting
that these domains are similarly folded. The N-terminal of the
crayfish protease, determined for the purified active enzyme,
aligns with position 94 in the BP10 sequence and position 121
in the BMP-1 sequence, just downstream of the basic peptides
RKKRK (BP10) and RSRSRR (BMP-1) which resemble many cleavage
sites by intracellular processing enzymes. This suggest that,
like most of the proteolytic enzymes, these proteases might be
synthesized as precursors and later processed by proteolytic
cleavage (Lepage et al., 1992).
SWISS_PROT: P42674
Subcellular location
At the early blastula stage, the protein is present in a diffuse pattern
in the perinuclear region suggesting that it is synthesized in the
endoplasmic reticulum surrounding the nuclei.
BP10 is predicted to be a secreted protein.
Immunolocalization of the BP10 protein
in whole embryos (and in individual cells from dissociated
embryos) clearly showed that in the hatching blastulas, the
BP10 protein is transported towards the apical face of the
epithelial cells, and can be seen just beneath the membrane
in older blastulas. As the predicted protein sequence does not
contain any putative hydrophobic transmembrane spanning region,
it is likely that BP10 is secreted into the perivitelline
space. Thus, the BP10 protein is synthesized and secreted
by ectoderm cells and probably acts
on the surface of the embryo (Lepage et al., 1992).
Expression Pattern
The BP10 mRNA is a zygotic gene product synthesized in the very
first hours following fertilization and activation
of the zygotic genome.
The 2.9 kb BP10 transcript begins to accumulate at the early blastula stage (about 128 cells),
reaches its highest level at the prehatching blastula stage
(8 hours, about 200 cells per embryo),
then decreases to an undetectable level when the blastula is hatched.
The BP10 protein is not detectable either in the unfertilized egg,
which indicates that there is no maternal BP10 protein, or in the
very early cleavage stages. It begins to be detected, albeit weakly,
at the early blastula stage (about 250 cells), its abundance peaks at the
prehatching and swimming blastula stages then decreases rapidly and remains
constant throughout development until the prism stage
which was the last analysed.
In all the labelled embryos,
the BP10 staining is restricted to a domain covering about half the embryo.
The localization of the BP10 protein correlates with the distribution of its mRNA.
Then it can be detected in an apical and submembranous position just before its secretion
into the perivitelline space. The protein is synthesized in a sharply
delimited continuous territory spanning about 70 % of the blastula.
Comparison of the size and orientation of the labelled territory
in the late blastula with the fate map of the blastula stage embryo
shows that the domain in which the BP10 gene is expressed
corresponds to the presumptive ectoderm (Lepage et al., 1992).
mRNA level
Temporal accumulation
Method 1: Northern blot analysis
Reference: Lepage et al., 1992
Method 2: Run-on assays
Reference: Lepage et al., 1992
| Stage |
Egg |
2 hr |
4 hr |
6.5 hr |
7.5 hr |
8.5 hr |
9.5 hr |
10.5 hr |
11.5 hr |
12.5 hr |
15 hr |
30 hr |
60 hr |
| Level |
- |
- |
- |
+ |
+ |
+ |
+ |
+ |
+ |
+ - |
- |
- |
- |
Protein level
Temporal accumulation
Method: Western blot analysis
Reference: Lepage et al., 1992
| Stage |
Egg |
16 cells |
Early blastula |
Prehatching blastula |
Swimming blastula |
Mesenchyme blastula |
Gastrula |
Prism |
| Level |
- |
- |
- |
+ |
+ |
+ |
+ |
+ |
Ectopic expression
Dissociated blastomeres
Expression of BP10 transcripts
Slot-blot hybridization showed that the pattern seen in intact embryos
was identical with the pattern described above.
In blastomers raised permanently in isolation,
the mRNA level increased with the same time course as intact embryos and reached
the ame peak value. However, where in normal embryos the transcripts
disappear rapidly, in isolated blastomeres their level begins to decrease
but then remains constant for many hours.
The abnormal pattern observed is independent of the association state of
blastomeres during the early stages and is not due to a prolonged Ca2+
deprivation and cannot be corrected by Ca2+ addition.
Thus the increase in transcripts level is indepenent of contacts and short-range
interactions between blastomeres.
Synthesis of BP10 protein
Blastomers were raised in isolation for ~ 10 h and stained with antibodies
directed against BP10.
The immunolabeling of individual blastomers resembled that observed in whole blastulae:
a single spot was visible on one side of the nucleus.
Furthermore, only two-thirds of the blastomeres were labeled.
This corresponds to the fraction of cells which synthesises the protein
in intact embryos, suggesting thta the same cells were labelled in both cases.
Thus, dissociation does not affect the inherent spatial control of this gene (Ghiglione et al., 1993)
Action of animalizing agents
Expression of BP10 transcripts
Slot-blot hybrydization showed that in embryos treated with Zn2+, the
time course of accumulation and decay as well as the maximal abundance were almost identical
to those in the control embryos.
Thus Zn2+ does not affect the control of the mRNA level.
BP10 protein localization
Immunolocalization of BP10 protein in prehatching blastulae embryos
raised in the presence of Zn2+ could not be distinguished
from that of the control embryos.
The labeling is restricted to the animal two-thirds of the embryo (Ghiglione et al., 1993).
Action of vegetalizing agents
Expression of BP10 transcripts
Embryos were exposed continuously to various concentrations of LiCl
ranging from 0 to 90 mM and the the maximal level of mRNA accumulation for each Li+
concentration was detected by densitometric scanning of the slot-blots. Li+
clearly decreased the amount of mRNA accumulation.
BP10 protein localization
Immunolocalization of BP10 protein in prehatching blastulae of embryos raised in the presence
of Li+ shows that the size of the territory in which protein is detected
is dramatically reduced. This effect is concentration - dependent,
as the Li+ concentration increases, the size of the territory decreases.
The effect of Li+ is time dependent. A maximal effect was obtained
when the Li+ incubation began within 30 min after fertilization.
This effect decreased if Li+ was added later, and completely
disappeared if lithium was added later than 6 h after fertilization, which is
the time when the transcription rate of the gene had nearly reached its
peak value in normal embryos (Ghiglione et al., 1993).
Sequences
GenBank:
Regulatory Regions
Regions
Regulatory Connections
Upstream Genes |
BP10 |
Downstream Genes |
Evolutionary Homologues
- tolloid Drosophila
- tolloid-related-1 Drosophila
- huBMP-1 human
- ASTPR Astacus crayfish
- SpAN Strongylocentrotus purpuratus
- SuBMP Strongylocentrotus purpuratus
Links
Urchin Web
Bibliography
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