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User:Vthompsonui

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Fall 2013

My Annotations

StatusPageDate/TimeGO Term (Aspect)ReferenceEvidenceNotesLinks
acceptableHUMAN:SF3B32013-09-10 19:06:45 CDTGO:0042177 negative regulation of protein catabolic process (P)PMID:23951410ECO:0000314 direct assay evidence used in manual assertion

In Figure 2, it is shown that transfection of SAP130 decreases the rate of degradation in p27 compared to an empty vector.

challenge
updatedbyinstructorSTRMU:Q8DT302013-09-10 19:29:48 CDTGO:0009312 oligosaccharide biosynthetic process (P)PMID:23930155ECO:0000314 direct assay evidence used in manual assertion

In figure 4, it is shown that maltooligosaccharides are formed after addition to the MalQ enzyme in a maltose substrate.

challenge
updatedbyinstructorARATH:KTI122013-09-24 19:15:18 CDTGO:0010449 root meristem growth (P)PMID:12615938ECO:0000315 mutant phenotype evidence used in manual assertion

Figure 2G shows that plants with wild type drl1 have proper primary root growth, while reduced root growth is seen in plants with a mutant form of drl1.

challenge
unacceptableXENTR:F6X1P42013-09-24 20:01:57 CDTGO:0061550 cranial ganglion development (P)PMID:24044555ECO:0000315 mutant phenotype evidence used in manual assertion

Figure 4D and E indicate that embryos with wild-type n4bp3 have normal cranial ganglia development, while those with a knockout mutation experience a high degree of abnormal cranial ganglion development

challenge
unacceptableXENTR:F6X1P42013-09-24 20:07:04 CDTGO:0048755 branching morphogenesis of a nerve (P)PMID:24044555ECO:0000315 mutant phenotype evidence used in manual assertion

Figures 4D shows that embryos with a knockout mutation in n4bp3 have significantly less branching points in their cranial nerves compared to the wild type.

challenge
unacceptableXENTR:F6X1P42013-09-24 20:16:06 CDTGO:0061564 axon development (P)PMID:24044555ECO:0000315 mutant phenotype evidence used in manual assertion

In Figure 3C and 3D, it is seen that embryos with a knockout mutation in n4bp3 show a significant lack of development in axonal branching than what is seen in the wild type

challenge
updatedbyinstructorMOUSE:WHRN2013-09-24 20:32:09 CDTGO:1990227 paranodal junction maintenance (P)PMID:24011083ECO:0000315 mutant phenotype evidence used in manual assertion

Figure 3 shows that sciatic nerves with whirlin mutants at various stages of development show abnormal paranodal formation compared to the wild type at the same stages of development.

challenge
acceptableMOUSE:WHRN2013-09-24 20:36:54 CDTGO:0021694 cerebellar Purkinje cell layer formation (P)PMID:24011083ECO:0000315 mutant phenotype evidence used in manual assertion

In Figure 5, Purkinje cells with whirlin knockout mutations show abnormal axonal growths that are not present on the wild type cells.

challenge
unacceptableMOUSE:Q8C0K82013-10-08 19:13:48 CDTGO:2000156 regulation of retrograde vesicle-mediated transport, Golgi to ER (P)PMID:24056303ECO:0000315 mutant phenotype evidence used in manual assertion

Figure 5a shows that a knockdown mutation of UVRAG impairs the ability of a protein complex associated with retrograde transport, and in figure 5b it is shown that the same knockdown results in inhibition of retrograde transport from the Golgi to the ER.

challenge
unacceptableMOUSE:Q8C0K82013-10-08 19:20:17 CDTGO:0051684 maintenance of Golgi location (P)PMID:24056303ECO:0000315 mutant phenotype evidence used in manual assertion

In Figure 6b, it is shown that knockdown mutations of UVRAG result in the dispersion of cis Golgi, whereas it is maintained maintained in a discrete structure in the control.

challenge
unacceptableMOUSE:Q8C0K82013-10-08 19:35:14 CDTGO:0010508 positive regulation of autophagy (P)PMID:24056303ECO:0000315 mutant phenotype evidence used in manual assertion

In Figure 8d, it is shown that knockdown mutations of UVRAG resulted in the improper autophagy induced dispersal of fluorescent Atg9, compared to the even dispersal seen in the control.

challenge
unacceptableMOUSE:BECN12013-10-08 19:38:20 CDTGO:0010508 positive regulation of autophagy (P)PMID:24056303ECO:0000315 mutant phenotype evidence used in manual assertion

In Figure 8d, it is shown that a knockdown mutation in beclin-1 results in the improper autophagy-induced dispersal of fluorescent Atg9, compared to an even dispersal in the control.

challenge
acceptableHUMAN:PSN12013-10-08 20:01:53 CDTGO:0045893 positive regulation of transcription, DNA-dependent (P)PMID:23794287ECO:0000315 mutant phenotype evidence used in manual assertion

In figure 2, it is shown that PS1 mutants in different mouse cells show significantly lower levels of p62 mRNA than in the wild type, indicating that PS1 has a positive effect on the transcription of the p62 gene.

challenge
acceptableARATH:WAT12013-11-05 18:07:44 CSTGO:0010315 auxin efflux (P)PMID:24129639ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in figure 4b, a mutant WAT1 transports significantly less auxin out of the cell than the wild type WAT1

challenge
acceptableRAT:BIG12013-11-05 18:23:54 CSTGO:0031175 neuron projection development (P)PMID:24090963ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in Figure 3A and B, a knockdown in wild type BIG1 led to a significant reduction in the development of neurites, or neuron projections.

challenge
acceptableRAT:BIG12013-11-05 18:37:46 CSTGO:0051897 positive regulation of protein kinase B signaling cascade (P)PMID:24090963ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in Figure 5C, knockdowns of BIG1 lead to significantly reduced phosphorylation of AKT in the protein kinase B signalling pathway, as compared to the wild type.

challenge
acceptableHUMAN:BECN12013-11-05 19:09:11 CSTGO:0006914 autophagy (P)PMID:24056303ECO:0000315 mutant phenotype evidence used in manual assertion

According to Supplemental Figure 7 a and b, a mutation in beclin-1 results in the improper autophagy-induced dispersal of of fluorescent Atg9, compared to an even dispersal in the control.

challenge
acceptableHUMAN:UVRAG2013-11-05 19:12:46 CSTGO:0006914 autophagy (P)PMID:24056303ECO:0000315 mutant phenotype evidence used in manual assertion

According to Supplementary Figure 7 a and b, , it is shown that knockdown mutations of UVRAG resulted in the improper autophagy induced dispersal of fluorescent Atg9, compared to the even dispersal seen in the control.

challenge
acceptableHUMAN:UVRAG2013-11-05 19:14:53 CSTGO:0051684 maintenance of Golgi location (P)PMID:24056303ECO:0000315 mutant phenotype evidence used in manual assertion

In Figure 6b, it is shown that knockdown mutations of UVRAG result in the dispersion of cis Golgi, whereas it is maintained maintained in a discrete structure in the control.

challenge
acceptableHUMAN:UVRAG2013-11-05 19:16:19 CSTGO:0006890 retrograde vesicle-mediated transport, Golgi to ER (P)PMID:24056303ECO:0000315 mutant phenotype evidence used in manual assertion

Figure 5a shows that a knockdown mutation of UVRAG impairs the ability of a protein complex associated with retrograde transport, and in figure 5b it is shown that the same knockdown results in inhibition of retrograde transport from the Golgi to the ER.

challenge
acceptableHUMAN:BECN12013-11-05 19:35:54 CSTGO:0007080 mitotic metaphase plate congression (P)PMID:23478334ECO:0000315 mutant phenotype evidence used in manual assertion

According to Figure 1e, knockdown of beclin 1 leads to a significant increase in misalignment at the metaphase plate during mitosis, compared to the almost negligible number of misalignments in the wild type.

challenge
acceptableHUMAN:UVRAG2013-11-05 19:41:16 CSTGO:0005783 endoplasmic reticulum (C)PMID:24056303ECO:0000314 direct assay evidence used in manual assertion

According to the various colocalization assays in Figure 2, UVRAG is found in the same cellular location as marker proteins classically used to mark the ER.

challenge
acceptableHUMAN:BECN12013-11-05 19:49:43 CSTGO:1902425 positive regulation of attachment of spindle microtubules to kinetochore involved in mitotic sister chromatid segregation (P)PMID:23478334ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in Figure 3B, a knockdown in Beclin 1 results in the improper attachment of microtubules to kinetochore proteins, as compared to the orderly attachment seen in the wild type.

challenge
acceptableMOUSE:BECN12013-11-05 20:03:30 CSTGO:0043652 engulfment of apoptotic cell (P)PMID:22393062ECO:0000315 mutant phenotype evidence used in manual assertion

According to Figure 2B, a knockdown in beclin 1 led to a significant increase in the engulfment of dead Jurkat cells compared to the wild type.

challenge
updatedbyinstructorMOUSE:BAKOR2013-11-05 20:38:10 CSTGO:0006914 autophagy (P)PMID:19270693ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in Figure 2a, knockdown of Atg14L leads to a buildup of autophagy substrates that accumulate only in the event of autophagy impairment, as opposed to the wild type where the substrate levels are negligible.

challenge

acceptable:14
unacceptable:7
requires_changes:0
flagged:0

Annotations challenged by Vthompsonui

StatusAuthor,GroupPageGO Term (Aspect)ReferenceEvidenceLinksPage history
updatedbyinstructorJpaulson1,
Team Pod1
SPHWW:A5VEL7GO:0047113 - aldehyde dehydrogenase (quinone) activity (F)PMID:23828599ECO:0000314 direct assay evidence used in manual assertionchallengeC: 3

fixed by Vthompsonui
updatedbyinstructorKamartens,
Team Bucky Lovers
ECOLI:DBHAGO:1990178 - HU-DNA complex (C)PMID:11278069ECO:0000314 direct assay evidence used in manual assertionchallengeC: 3

fixed by Kohli3
updatedbyinstructorKsylvester,
Team Loony Toons
YEAST:SNU66GO:0005634 - nucleus (C)PMID:15620657ECO:0000314 direct assay evidence used in manual assertionchallengeC: 4

fixed by Vthompsonui
updatedbyinstructorAkreda,
Team Stones Throw
MEASE:MATRXGO:0019013 - viral nucleocapsid (C)PMID:113558ECO:0000314 direct assay evidence used in manual assertionchallengeC: 2

fixed by Vthompsonui
updatedbyinstructorKohli3,
Team WhiteShyPaulCo
HPV16:VE6GO:0039653 - suppression by virus of host transcription (P)PMID:10400710ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 3

fixed by Kohli3
updatedbyinstructorKrbrown6,
Team 4 peas in a pod
VIBF1:Q5DYR1GO:0035885 - exochitinase activity (F)PMID:22233679ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 2

fixed by Vthompsonui
unacceptableRepasy,
Team 4 peas in a pod
MYCTU:RPFEGO:0010628 - positive regulation of gene expression (P)PMID:23554726ECO:0000314 direct assay evidence used in manual assertionchallengeC: 1
updatedbyinstructorAtruchon,
Team Hu Ville
RALSO:Q8XZS6GO:0033320 - UDP-D-xylose biosynthetic process (P)PMID:20118241ECO:0000314 direct assay evidence used in manual assertionchallengeC: 5

fixed by Roosheel
updatedbyinstructorKwindschitl,
Team Bucky Lovers
BACTU:AHLLGO:1901335 - lactone catabolic process (P)PMID:18852506ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 1
unacceptableEmuehlenkamp,
Team Bucky's Bugs
DROME:TERAGO:0046907 - intracellular transport (P)PMID:23790629ECO:0000255 match to sequence model evidence used in manual assertionchallengeC: 2
unacceptableBtilkens,
Team Protein Pushers
FUSCU:A1XCI9PMID:17584451ECO:0000255 match to sequence model evidence used in manual assertionchallengeC: 1
unacceptableDelwadia,
Team People that mess up
HUMAN:HSPB1GO:0046596 - regulation of viral entry into host cell (P)PMID:24098578ECO:0000314 direct assay evidence used in manual assertionchallengeC: 1
updatedbyinstructorVthompsonui,
Team Buster McThunderstick
MOUSE:WHRNGO:1990227 - paranodal junction maintenance (P)PMID:24011083ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 3
unacceptableKrbrown6,
Team 4 peas in a pod
FRATL:Q7X168GO:0002437 - inflammatory response to antigenic stimulus (P)PMID:19233475ECO:0000314 direct assay evidence used in manual assertionchallengeC: 2
unacceptableRoosheel,
Team Thoth
PSEAE:CATAGO:0043580 - periplasmic space organization (P)PMID:10913088ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 1
updatedbyinstructorAajones4,
Team Pitbull Hurricanes
BACAN:Q81YT0GO:0044847 - iron acquisition from host (P)PMID:22865843ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 3
updatedbyinstructorNlad,
Team Niraali
STRMU:Q8DVD0GO:0045892 - negative regulation of transcription, DNA-templated (P)PMID:12399506ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 2

fixed by Vthompsonui
updatedbyinstructorNlad,
Team Niraali
STRMU:Q8DS13GO:0045892 - negative regulation of transcription, DNA-templated (P)PMID:12399506ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 2

fixed by Vthompsonui
updatedbyinstructorNlad,
Team Niraali
STRMU:CLPPGO:0045892 - negative regulation of transcription, DNA-templated (P)PMID:12399506ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 1

fixed by Vthompsonui

7 annotations fixed by Vthompsonui


Spring 2013

My Annotations

StatusPageDate/TimeGO Term (Aspect)ReferenceEvidenceNotesLinks
acceptableHUMAN:MERTK2013-02-05 19:20:42 CSTGO:2000107 negative regulation of leukocyte apoptotic process (P)PMID:23353780ECO:0000315 mutant phenotype evidence used in manual assertion

It is shown in figure 3 that a knockout mutation in MerTK leads to increased apoptosis rates in response to chemotherapeutic agents.

challenge
unacceptableHUMAN:MERTK2013-02-05 19:23:55 CSTGO:0071866 negative regulation of apoptotic process in bone marrow (P)PMID:23353780ECO:0000315 mutant phenotype evidence used in manual assertion

It is shown in figure 3 that a knockout mutation in MerTK leads to increased apoptosis rates in response to chemotherapeutic agents.

challenge
correctedthroughchallengesMOUSE:BMP22013-02-05 19:47:59 CSTGO:0006355 regulation of transcription, DNA-dependent (P)PMID:11788714ECO:0000314 direct assay evidence used in manual assertion

It is shown by figure 1 through a direct assay that BMP-2 is involved in the induction of Dlx-3 transcription.

challenge
unacceptableMOUSE:BMP22013-02-05 19:50:17 CSTGO:2000383 regulation of ectoderm development (P)PMID:11788714ECO:0000314 direct assay evidence used in manual assertion

It is shown by figure 6 through a direct assay that BMP induces the Dlx-3 homeodomain, which regulates patterning in the embryonic ectoderm.

challenge
unacceptableMOUSE:SMAD12013-02-05 20:00:35 CSTGO:0030509 BMP signaling pathway (P)PMID:11788714ECO:0000314 direct assay evidence used in manual assertion

It is shown by figure 3 through a direct assay that Smad1 binds to an area of the Dlx-3 homeodomain that is responsive to BMP-2 signaling.

challenge
unacceptableMOUSE:SMAD12013-02-05 20:06:02 CSTGO:0007398 ectoderm development (P)PMID:11788714ECO:0000314 direct assay evidence used in manual assertion

It is shown by figure 3 through a direct assay that Smad1 binds to a promoter on the homeodomain Dlx-3 which regulates patterning in the embryonic ectoderm

challenge
unacceptableMOUSE:SMAD42013-02-05 20:11:09 CSTGO:0030509 BMP signaling pathway (P)PMID:11788714ECO:0000314 direct assay evidence used in manual assertion

It is shown by figure 3 through a direct assay that Smad4 binds to a promoter for the homeodomain Dlx-3 that is responsive to signaling by BMP-2.

challenge
unacceptableMOUSE:SMAD42013-02-05 20:14:37 CSTGO:0007398 ectoderm development (P)PMID:11788714ECO:0000314 direct assay evidence used in manual assertion

It is shown by figure 3 through a direct assay that Smad4 binds to a promoter for Dlx-3, which is known to regulate patterning in the embyronic ectoderm.

challenge
unacceptableMOUSE:BMP22013-02-12 18:22:22 CSTGO:0042733 embryonic digit morphogenesis (P)PMID:8682290ECO:0000314 direct assay evidence used in manual assertion

As evidenced in figure 4 by the in situ hybridization, BMP-2 RNA transcripts are present in the terminal ends of the digits as they develop from the forelimb.

challenge
acceptableECOLI:FTSK2013-02-19 19:46:14 CSTGO:0051301 cell division (P)PMID:21091498ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in figure 5, cells with a deletion mutation of varying parts of FtsK form elongate rods, which is indicative of the cell's inability to divide.

challenge
acceptableECOLI:FTSK2013-02-19 20:28:53 CSTGO:0016887 ATPase activity (F)PMID:20081205ECO:0000314 direct assay evidence used in manual assertion

As indicated in figure 5, ATP is hydrolyzed at a significantly greater rate when FtsK is introduced.

challenge
acceptableBACSU:YPBR2013-03-05 18:27:17 CSTGO:0090529 cell septum assembly (P)PMID:23249255ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in figure 1, cells with a deletion mutation in the gene for ypbR developed double septa during cytokinesis.

challenge
updatedbyinstructorBACSU:EZRA2013-03-05 18:40:14 CSTGO:0051781 positive regulation of cell division (P)PMID:23249255ECO:0000315 mutant phenotype evidence used in manual assertion

As show in Figure 1, a deletion mutation of the gene encoding EzrA leads to improper partitioning of a cell into its daughter cells

challenge
updatedbyinstructorHUMAN:MAOX2013-03-26 19:35:17 CDTGO:0004470 malic enzyme activity (F)PMID:23334421ECO:0000315 mutant phenotype evidence used in manual assertion

Fig 1C.

challenge
updatedbyinstructorHUMAN:MAOM2013-03-26 20:06:37 CDTGO:0004470 malic enzyme activity (F)PMID:23334421ECO:0000315 mutant phenotype evidence used in manual assertion

Fig 1C.

challenge
acceptableHUMAN:MAOX2013-04-09 19:07:29 CDTGO:1902031 regulation of NADP metabolic process (P)PMID:23334421ECO:0000315 mutant phenotype evidence used in manual assertion

In figure 2, it is shown that relative to Malic Enzyme mutants that show no enzymatic activity, wild type Malic Enzyme leads to greater production of NADPH in a cell.

challenge
acceptableHUMAN:MAOM2013-04-09 19:11:39 CDTGO:1902031 regulation of NADP metabolic process (P)PMID:23334421ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in figure 2, the level of NADPH in the cell is comparatively greater in cells with wild type Malic Enzyme 2 than with Malic Enzyme 2 mutants that had no enzymatic activity.

challenge
updatedbyinstructorMOUSE:UPP12013-04-09 19:37:04 CDTGO:0006218 uridine catabolic process (P)PMID:23355744ECO:0000314 direct assay evidence used in manual assertion

As shown in figure 1, a mutant of uridine phosphorylase in the liver with markedly higher enzymatic content led to a significant increase in beta alanine content in the liver compared to the wild type.

challenge
updatedbyinstructorMOUSE:SMAD42013-04-09 20:41:21 CDTGO:0042733 embryonic digit morphogenesis (P)PMID:23034633ECO:0000315 mutant phenotype evidence used in manual assertion

As shown in figures 1 and 2, inactivation of Smad4 leads to a lack of development in the skeletal portion of embryonic digits.

challenge
updatedbyinstructorMYCTU:PAT2013-04-11 11:09:55 CDTGO:0016746 transferase activity, transferring acyl groups (F)PMID:21627103ECO:0000314 direct assay evidence used in manual assertion

It is shown in Figure 1B that the protein acetyltransferase binds an acetyl group, and in Figure 3B that the acetyl group is transfered to Acetyl CoA Synthetase.

challenge
acceptableMYCTU:NPD2013-04-11 11:18:54 CDTGO:0006476 protein deacetylation (P)PMID:21627103ECO:0000314 direct assay evidence used in manual assertion

As shown in figure 5, Acetyl CoA synthetase with a fluorescently marked chloracetyl group was lowered in fluorescent intensity when Rv1151c was added, indicating that Rv1151c deacetylated the protein.

challenge
requireschangesMYCTU:ACSA2013-04-11 11:43:43 CDTGO:0006476 protein deacetylation (P)PMID:21627103ECO:0000314 direct assay evidence used in manual assertion

It is shown in figure 3 that ACS is strongly fluorescently labelled after exposure to MsPat with a fluorescent chloracetyl group bound to it, indicating that ACS deacetylated the protein.

challenge

acceptable:7
unacceptable:7
requires_changes:1
flagged:0

Annotations challenged by Vthompsonui

StatusAuthor,GroupPageGO Term (Aspect)ReferenceEvidenceLinksPage history
updatedbyinstructorKpatel,
Team Llamarmy
DANRE:Q7ZU02GO:0008283 - cell population proliferation (P)PMID:22782722ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 3

fixed by Cwolterman
updatedbyinstructorShall,
Team Robots In Disguise
RAT:D3ZZQ0GO:0050775 - positive regulation of dendrite morphogenesis (P)PMID:21048137ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 7

fixed by Lfileccia
updatedbyinstructorShall,
Team Robots In Disguise
HUMAN:MINK1GO:0006468 - protein phosphorylation (P)PMID:21690388ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 2

fixed by Shoffnung
correctedthroughchallengesAyusol,
Team Viral Load Challengers
9FLAV:A0MNX0GO:0036338 - viral membrane (C)PMID:23300717ECO:0000314 direct assay evidence used in manual assertionchallengeC: 4

fixed by Kathrynmartin
updatedbyinstructorCwolterman,
Team Pinball Wizards
HUMAN:IL4GO:0010633 - negative regulation of epithelial cell migration (P)PMID:11698262ECO:0000314 direct assay evidence used in manual assertionchallengeC: 2

fixed by Jbeasley
updatedbyinstructorI.bargsley,
Team Don't be anno-hating
MOUSE:NSUN2GO:0033391 - chromatoid body (C)PMID:23401851ECO:0000314 direct assay evidence used in manual assertionchallengeC: 2

fixed by I.bargsley
updatedbyinstructorI.bargsley,
Team Don't be anno-hating
MOUSE:GAB2GO:0010634 - positive regulation of epithelial cell migration (P)PMID:23401857ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 2

fixed by I.bargsley
updatedbyinstructorAcoppola,
Team CFP
DROME:Q9NGK5GO:0050805 - negative regulation of synaptic transmission (P)PMID:21228178ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 5
requireschangesEstherchung,
Team CFP
MOUSE:VIMEGO:0010762 - regulation of fibroblast migration (P)PMID:21346197ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 1
updatedbyinstructorDimitrios.Spantithos,
Team Gene Shalit
ECOLI:YBJNGO:0009297 - pilus assembly (P)PMID:21980417ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 1

fixed by Vthompsonui
updatedbyinstructorEmeller,
Team The Z-team
DANRE:A2AWU1GO:0061075 - positive regulation of neural retina development (P)PMID:18667622ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 1

fixed by Vthompsonui
requireschangesSinghpr4,
Team The Monstars
9GAMM:C8YX85GO:1902087 - dimethylsulfoniopropionate catabolic process (P)PMID:19807777ECO:0000314 direct assay evidence used in manual assertionchallengeC: 3
updatedbyinstructorPriesko4,
Team ttKtt
ARTAU:Q6SJY7GO:0004040 - amidase activity (F)PMID:16885454ECO:0000314 direct assay evidence used in manual assertionchallengeC: 2

fixed by Priesko4
updatedbyinstructorMegan.Bosson,
Team Amino Acid
DANRE:INVSGO:0005929 - cilium (C)PMID:21602787ECO:0000314 direct assay evidence used in manual assertionchallengeC: 2

fixed by Sabrinamoisan
updatedbyinstructorFinchcha,
Team We Love Nickelback
EMEND:Q00171GO:0045893 - positive regulation of transcription, DNA-templated (P)PMID:16467464ECO:0000315 mutant phenotype evidence used in manual assertionchallengeC: 3

2 annotations fixed by Vthompsonui

What do the icons mean in the status column?

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