| Type |
Details |
Score |
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
599
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
940
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
262
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
310
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
259
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
259
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
600
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
239
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
940
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
797
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
109
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
239
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
996
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
1979
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
178
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
262
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
272
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
970
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
244
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
196
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
272
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
250
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
600
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
529
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
248
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
673
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
397
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
970
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
147
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Gibbs GM |
| Year: |
2008 |
| Journal: |
Endocr Rev |
| Title: |
The CAP superfamily: cysteine-rich secretory proteins, antigen 5, and pathogenesis-related 1 proteins--roles in reproduction, cancer, and immune defense. |
| Volume: |
29 |
| Issue: |
7 |
| Pages: |
865-97 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Lembo PM |
| Year: |
2002 |
| Journal: |
Nat Neurosci |
| Title: |
Proenkephalin A gene products activate a new family of sensory neuron--specific GPCRs. |
| Volume: |
5 |
| Issue: |
3 |
| Pages: |
201-9 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Robas N |
| Year: |
2003 |
| Journal: |
J Biol Chem |
| Title: |
MrgX2 is a high potency cortistatin receptor expressed in dorsal root ganglion. |
| Volume: |
278 |
| Issue: |
45 |
| Pages: |
44400-4 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Yang S |
| Year: |
2005 |
| Journal: |
Gene |
| Title: |
Adaptive evolution of MRGX2, a human sensory neuron specific gene involved in nociception. |
| Volume: |
352 |
|
| Pages: |
30-5 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Kamohara M |
| Year: |
2005 |
| Journal: |
Biochem Biophys Res Commun |
| Title: |
Identification of MrgX2 as a human G-protein-coupled receptor for proadrenomedullin N-terminal peptides. |
| Volume: |
330 |
| Issue: |
4 |
| Pages: |
1146-52 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Schauder CM |
| Year: |
2014 |
| Journal: |
Nature |
| Title: |
Structure of a lipid-bound extended synaptotagmin indicates a role in lipid transfer. |
| Volume: |
510 |
| Issue: |
7506 |
| Pages: |
552-5 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
RodrÃguez A |
| Year: |
2009 |
| Journal: |
Mol Cell |
| Title: |
A conserved docking surface on calcineurin mediates interaction with substrates and immunosuppressants. |
| Volume: |
33 |
| Issue: |
5 |
| Pages: |
616-26 |
|
•
•
•
•
•
|
| Protein Domain |
| Type: |
Domain |
| Description: |
The cysteine-rich secretory proteins, antigen 5, and pathogenesis-related 1 proteins (CAP) superfamily proteins are found in a wide range of organisms, including prokaryotes []and non-vertebrate eukaryotes [], The nine subfamilies of the mammalian CAP superfamily include: the human glioma pathogenesis-related 1 (GLIPR1), Golgi associated pathogenesis related-1 (GAPR1) proteins, peptidase inhibitor 15 (PI15), peptidase inhibitor 16 (PI16), cysteine-rich secretory proteins (CRISPs), CRISP LCCL domain containing 1 (CRISPLD1), CRISP LCCL domain containing 2 (CRISPLD2), mannose receptor like and the R3H domain containing like proteins. Members are most often secreted and have an extracellular endocrine or paracrine function and are involved in processes including the regulation of extracellular matrix and branching morphogenesis, potentially as either proteases or protease inhibitors; in ion channel regulation in fertility; as tumour suppressor or pro-oncogenic genes in tissues including the prostate; and in cell-cell adhesion during fertilisation. The overall protein structural conservation within the CAP superfamily results in fundamentally similar functions for the CAP domain in all members, yet the diversity outside of this core region dramatically alters the target specificity and, thus, the biological consequences []. The Ca2-chelating function []would fit with the various signalling processes (e.g. the CRISP proteins) that members of this family are involved in, and also the sequence and structural evidence of a conserved pocket containing two histidines and a glutamate. It also may explain how blocks the Ca2 transporting ryanodine receptors. This entry represents the CAP domain common to all members of the CAP superfamily. The CAP domain forms a unique 3 layer α-β-α fold with some, though not all, of the structural elements found in proteases []. |
|
•
•
•
•
•
|
| Protein Domain |
| Type: |
Domain |
| Description: |
The cysteine-rich secretory proteins, antigen 5, and pathogenesis-related 1 proteins (CAP) superfamily proteins are found in a wide range of organisms, including prokaryotes []and non-vertebrate eukaryotes [], The nine subfamilies of the mammalian CAP superfamily include: the human glioma pathogenesis-related 1 (GLIPR1), Golgi associated pathogenesis related-1 (GAPR1) proteins, peptidase inhibitor 15 (PI15), peptidase inhibitor 16 (PI16), cysteine-rich secretory proteins (CRISPs), CRISP LCCL domain containing 1 (CRISPLD1), CRISP LCCL domain containing 2 (CRISPLD2), mannose receptor like and the R3H domain containing like proteins. Members are most often secreted and have an extracellular endocrine or paracrine function and are involved in processes including the regulation of extracellular matrix and branching morphogenesis, potentially as either proteases or protease inhibitors; in ion channel regulation in fertility; as tumour suppressor or pro-oncogenic genes in tissues including the prostate; and in cell-cell adhesion during fertilisation. The overall protein structural conservation within the CAP superfamily results in fundamentally similar functions for the CAP domain in all members, yet the diversity outside of this core region dramatically alters the target specificity and, thus, the biological consequences []. The Ca2-chelating function []would fit with the various signalling processes (e.g. the CRISP proteins) that members of this family are involved in, and also the sequence and structural evidence of a conserved pocket containing two histidines and a glutamate. It also may explain how blocks the Ca2 transporting ryanodine receptors. This entry represents a subgroup of the CAP domains found only in bacteria capable of endospore formation. Proteins containing this domain include YkwD of Bacillus subtilis. This domain is generally found at the C-terminal region of these proteins, while the N-terminal region sometimes contains a domain homologous to the spore coat assembly protein SafA (). |
|
•
•
•
•
•
|
| Protein Domain |
| Type: |
Family |
| Description: |
Members of the mas-related receptor family (also known as oncogene-like MAS and mas-related G-protein coupled receptor MRG) have been implicated in the development, regulation and function of nociceptive neurons, specifically in the modulation of pain. Most members are orphaned, with no endogeneous ligand identified. Of the human mas-related GPCRs, four (MRGPRD, MRGPRE, MRGPRF and MRGPRG) are also found in rodents, whereas MRGPRX1, MRGPRX2, MRGPRX3 and MRGPRX4 are found exclusively in primates. Certain rodent MRGs have been reported to respond to adenine []and to RF-amide peptides, including neuropeptide FF [, ], but the relevance of these findings to man is unclear. MRGs are expressed predominantly in small diameter sensory neurons of the dorsal root ganglia, where there is emerging evidence that they may be mediators of histamine-independent itch [, ].This entry represents Mas-related G protein-coupled receptor X1 and X2.Mas-related G protein-coupled receptor X1 (MRGPRX1) is thought to be involved with nociceptor function and development, and in the modulation of pain. The receptor is currently orphaned, no specific endogenous ligand having been identified. However, it may potently be activated by enkephalins: BAM22 evokes a large and dose-dependent release of intracellular calcium in cells stably transfected with the receptor []. Mas-related G protein-coupled receptor X2 (MRGPRX2) is thought to be involved with nociceptor function and development, and directly involved in the modulation of pain. The receptor is currently orphaned, no specific endogenous ligand having been identified. However, it may be activated by neuropeptides: stimulation by cortistatin-14 in receptor-expressing cells potently increases intracellular Ca2 [, ]. MRGPRX2 is also thought to be a human PAMP-12 receptor that regulates catecholamine secretion from adrenal glands []. |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Benthall KN |
| Year: |
2021 |
| Journal: |
Cell Rep |
| Title: |
Loss of Tsc1 from striatal direct pathway neurons impairs endocannabinoid-LTD and enhances motor routine learning. |
| Volume: |
36 |
| Issue: |
6 |
| Pages: |
109511 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Albergaria C |
| Year: |
2018 |
| Journal: |
Nat Neurosci |
| Title: |
Locomotor activity modulates associative learning in mouse cerebellum. |
| Volume: |
21 |
| Issue: |
5 |
| Pages: |
725-735 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Gao FJ |
| Year: |
2021 |
| Journal: |
Acta Neuropathol Commun |
| Title: |
Forebrain Shh overexpression improves cognitive function and locomotor hyperactivity in an aneuploid mouse model of Down syndrome and its euploid littermates. |
| Volume: |
9 |
| Issue: |
1 |
| Pages: |
137 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Mateo C |
| Year: |
2017 |
| Journal: |
Neuron |
| Title: |
Entrainment of Arteriole Vasomotor Fluctuations by Neural Activity Is a Basis of Blood-Oxygenation-Level-Dependent "Resting-State" Connectivity. |
| Volume: |
96 |
| Issue: |
4 |
| Pages: |
936-948.e3 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Benthall KN |
| Year: |
2018 |
| Journal: |
Cell Rep |
| Title: |
Corticostriatal Transmission Is Selectively Enhanced in Striatonigral Neurons with Postnatal Loss of Tsc1. |
| Volume: |
23 |
| Issue: |
11 |
| Pages: |
3197-3208 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Balbi M |
| Year: |
2021 |
| Journal: |
Cell Rep |
| Title: |
Gamma frequency activation of inhibitory neurons in the acute phase after stroke attenuates vascular and behavioral dysfunction. |
| Volume: |
34 |
| Issue: |
5 |
| Pages: |
108696 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Plotkin JL |
| Year: |
2014 |
| Journal: |
Neuron |
| Title: |
Impaired TrkB receptor signaling underlies corticostriatal dysfunction in Huntington's disease. |
| Volume: |
83 |
| Issue: |
1 |
| Pages: |
178-88 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Wang X |
| Year: |
2017 |
| Journal: |
Cell |
| Title: |
Deconstruction of Corticospinal Circuits for Goal-Directed Motor Skills. |
| Volume: |
171 |
| Issue: |
2 |
| Pages: |
440-455.e14 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Wu YW |
| Year: |
2015 |
| Journal: |
Cell Rep |
| Title: |
Input- and cell-type-specific endocannabinoid-dependent LTD in the striatum. |
| Volume: |
10 |
| Issue: |
1 |
| Pages: |
75-87 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Jackman SL |
| Year: |
2020 |
| Journal: |
Elife |
| Title: |
Cerebellar Purkinje cell activity modulates aggressive behavior. |
| Volume: |
9 |
|
|
|
•
•
•
•
•
|
| Publication |
| First Author: |
Matityahu L |
| Year: |
2022 |
| Journal: |
Elife |
| Title: |
A tonic nicotinic brake controls spike timing in striatal spiny projection neurons. |
| Volume: |
11 |
|
|
|
•
•
•
•
•
|
| Publication |
| First Author: |
Vecchia D |
| Year: |
2020 |
| Journal: |
Curr Biol |
| Title: |
Temporal Sharpening of Sensory Responses by Layer V in the Mouse Primary Somatosensory Cortex. |
| Volume: |
30 |
| Issue: |
9 |
| Pages: |
1589-1599.e10 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Oz O |
| Year: |
2022 |
| Journal: |
Elife |
| Title: |
Non-uniform distribution of dendritic nonlinearities differentially engages thalamostriatal and corticostriatal inputs onto cholinergic interneurons. |
| Volume: |
11 |
|
|
|
•
•
•
•
•
|
| Publication |
| First Author: |
Arenkiel BR |
| Year: |
2007 |
| Journal: |
Neuron |
| Title: |
In vivo light-induced activation of neural circuitry in transgenic mice expressing channelrhodopsin-2. |
| Volume: |
54 |
| Issue: |
2 |
| Pages: |
205-18 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Brunner C |
| Year: |
2020 |
| Journal: |
Neuron |
| Title: |
A Platform for Brain-wide Volumetric Functional Ultrasound Imaging and Analysis of Circuit Dynamics in Awake Mice. |
| Volume: |
108 |
| Issue: |
5 |
| Pages: |
861-875.e7 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Luis-Islas J |
| Year: |
2022 |
| Journal: |
eNeuro |
| Title: |
Optoception: Perception of Optogenetic Brain Perturbations. |
| Volume: |
9 |
| Issue: |
3 |
|
|
•
•
•
•
•
|
| Publication |
| First Author: |
Herman AM |
| Year: |
2014 |
| Journal: |
Elife |
| Title: |
Cell type-specific and time-dependent light exposure contribute to silencing in neurons expressing Channelrhodopsin-2. |
| Volume: |
3 |
|
| Pages: |
e01481 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Berglund K |
| Year: |
2006 |
| Journal: |
Brain Cell Biol |
| Title: |
Imaging synaptic inhibition in transgenic mice expressing the chloride indicator, Clomeleon. |
| Volume: |
35 |
| Issue: |
4-6 |
| Pages: |
207-28 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Duebel J |
| Year: |
2006 |
| Journal: |
Neuron |
| Title: |
Two-photon imaging reveals somatodendritic chloride gradient in retinal ON-type bipolar cells expressing the biosensor Clomeleon. |
| Volume: |
49 |
| Issue: |
1 |
| Pages: |
81-94 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Berglund K |
| Year: |
2008 |
| Journal: |
Brain Cell Biol |
| Title: |
Imaging synaptic inhibition throughout the brain via genetically targeted Clomeleon. |
| Volume: |
36 |
| Issue: |
1-4 |
| Pages: |
101-18 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Rodriguez-Garcia A |
| Year: |
2014 |
| Journal: |
Proc Natl Acad Sci U S A |
| Title: |
GAP, an aequorin-based fluorescent indicator for imaging Ca2+ in organelles. |
| Volume: |
111 |
| Issue: |
7 |
| Pages: |
2584-9 |
|
•
•
•
•
•
|
| Protein Coding Gene |
| Type: |
protein_coding_gene |
| Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
| Protein Coding Gene |
| Type: |
protein_coding_gene |
| Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
| Protein Coding Gene |
| Type: |
protein_coding_gene |
| Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
| Protein Coding Gene |
| Type: |
protein_coding_gene |
| Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
| Protein Coding Gene |
| Type: |
protein_coding_gene |
| Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
| Protein Coding Gene |
| Type: |
protein_coding_gene |
| Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
| Protein Coding Gene |
| Type: |
protein_coding_gene |
| Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
| Allele |
| Name: |
GLI-Kruppel family member GLI3; polydactyly Nagoya |
| Allele Type: |
Spontaneous |
| Attribute String: |
Hypomorph |
|
•
•
•
•
•
|
| Allele |
| Name: |
Fyn proto-oncogene; targeted mutation 1, Philippe Soriano |
| Allele Type: |
Targeted |
| Attribute String: |
Null/knockout |
|
•
•
•
•
•
|
| Allele |
| Name: |
low density lipoprotein receptor-related protein 8, apolipoprotein e receptor; targeted mutation 1, Joachim Herz |
| Allele Type: |
Targeted |
| Attribute String: |
Null/knockout |
|
•
•
•
•
•
|
| Allele |
| Name: |
LIM homeobox transcription factor 1 alpha; dreher Jackson |
| Allele Type: |
Spontaneous |
|
|
•
•
•
•
•
|
| Transgene |
| Type: |
transgene |
| Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
| Allele |
| Name: |
etoposide induced 2.4 mRNA; targeted mutation 1, Hong Zhang |
| Allele Type: |
Targeted |
| Attribute String: |
Conditional ready, No functional change |
|
•
•
•
•
•
|
| Allele |
| Name: |
ectopic P-granules 5 autophagy tethering factor; targeted mutation 1, Yan G Zhao |
| Allele Type: |
Targeted |
| Attribute String: |
Null/knockout |
|
•
•
•
•
•
|
| Allele |
| Name: |
BICD cargo adaptor 2; targeted mutation 1.1, Casper Hoogenraad |
| Allele Type: |
Targeted |
| Attribute String: |
Null/knockout |
|
•
•
•
•
•
|
| Allele |
| Name: |
bromodomain and PHD finger containing, 1; targeted mutation 1c, Wellcome Trust Sanger Institute |
| Allele Type: |
Targeted |
| Attribute String: |
Conditional ready |
|
•
•
•
•
•
|
| Genotype |
| Symbol: |
Fyn/Fyn |
| Background: |
involves: 129S7/SvEvBrd * C57BL/6J |
| Zygosity: |
hm |
| Has Mutant Allele: |
true |
|
•
•
•
•
•
|
| Genotype |
| Symbol: |
Pten/Pten Tg(Gfap-cre)1Sbk/? |
| Background: |
involves: 129P2/OlaHsd |
| Zygosity: |
cn |
| Has Mutant Allele: |
true |
|
•
•
•
•
•
|
| Genotype |
| Symbol: |
Tsc1/Tsc1 Tg(Syn1-cre)671Jxm/? |
| Background: |
involves: 129S4/SvJae * C57BL/6 * CBA |
| Zygosity: |
cn |
| Has Mutant Allele: |
true |
|
•
•
•
•
•
|
| Genotype |
| Symbol: |
Macf1/Macf1 Tg(Nes-cre)1Kln/? |
| Background: |
involves: 129S6/SvEvTac * C57BL/6 * FVB/N * SJL |
| Zygosity: |
cn |
| Has Mutant Allele: |
true |
|
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•
•
•
•
|
| Genotype |
| Symbol: |
Tg(Dyrk1a)189N3Yah/? |
| Background: |
B6.129P2-Tg(Dyrk1a)189N3Yah/Yah |
| Zygosity: |
ot |
| Has Mutant Allele: |
true |
|
•
•
•
•
•
|
| Genotype |
| Symbol: |
Eml1/Eml1 |
| Background: |
C57BL/6N-Eml1 |
| Zygosity: |
hm |
| Has Mutant Allele: |
true |
|
•
•
•
•
•
|
| Genotype |
| Symbol: |
Rogdi/Rogdi |
| Background: |
involves: C57BL/6N |
| Zygosity: |
hm |
| Has Mutant Allele: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
171
 |
| Fragment?: |
true |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
172
 |
| Fragment?: |
false |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Whittington DA |
| Year: |
2004 |
| Journal: |
J Biol Chem |
| Title: |
Expression, assay, and structure of the extracellular domain of murine carbonic anhydrase XIV: implications for selective inhibition of membrane-associated isozymes. |
| Volume: |
279 |
| Issue: |
8 |
| Pages: |
7223-8 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Savinova OV |
| Year: |
2001 |
| Journal: |
BMC Genet |
| Title: |
Intraocular pressure in genetically distinct mice: an update and strain survey. |
| Volume: |
2 |
|
| Pages: |
12 |
|
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•
•
•
•
|
| Publication |
| First Author: |
Jaquenod De Giusti C |
| Year: |
2019 |
| Journal: |
J Mol Cell Cardiol |
| Title: |
Carbonic anhydrase II/sodium-proton exchanger 1 metabolon complex in cardiomyopathy of ob-/- type 2 diabetic mice. |
| Volume: |
136 |
|
| Pages: |
53-63 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Leppilampi M |
| Year: |
2005 |
| Journal: |
Proc Natl Acad Sci U S A |
| Title: |
Carbonic anhydrase isozyme-II-deficient mice lack the duodenal bicarbonate secretory response to prostaglandin E2. |
| Volume: |
102 |
| Issue: |
42 |
| Pages: |
15247-52 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Barone S |
| Year: |
2021 |
| Journal: |
Proc Natl Acad Sci U S A |
| Title: |
Kidney intercalated cells and the transcription factor FOXi1 drive cystogenesis in tuberous sclerosis complex. |
| Volume: |
118 |
| Issue: |
6 |
|
|
•
•
•
•
•
|
| Publication |
| First Author: |
Dou H |
| Year: |
2004 |
| Journal: |
J Histochem Cytochem |
| Title: |
Co-expression of pendrin, vacuolar H+-ATPase alpha4-subunit and carbonic anhydrase II in epithelial cells of the murine endolymphatic sac. |
| Volume: |
52 |
| Issue: |
10 |
| Pages: |
1377-84 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Davisson MT |
| Year: |
1976 |
| Journal: |
J Hered |
| Title: |
Genes on chromosome 3 of the mouse. |
| Volume: |
67 |
| Issue: |
3 |
| Pages: |
155-6 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Eicher EM |
| Year: |
1976 |
| Journal: |
Biochem Genet |
| Title: |
Evolution of mammalian carbonic anhydrase loci by tanden duplication: close linkage of Car-1 and Car-2 to the centromere region of chromosome 3 of the mouse. |
| Volume: |
14 |
| Issue: |
7-8 |
| Pages: |
651-60 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Racine RR |
| Year: |
1980 |
| Journal: |
Biochem Genet |
| Title: |
Genetic analysis of protein variations in Mus musculus using two-dimensional electrophoresis. |
| Volume: |
18 |
| Issue: |
1-2 |
| Pages: |
185-97 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Heuckeroth RO |
| Year: |
1987 |
| Journal: |
J Biol Chem |
| Title: |
Analysis of the tissue-specific expression, developmental regulation, and linkage relationships of a rodent gene encoding heart fatty acid binding protein. |
| Volume: |
262 |
| Issue: |
20 |
| Pages: |
9709-17 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Paul PR |
| Year: |
1987 |
| Journal: |
Biochem Genet |
| Title: |
Analysis of the mouse Amy locus in recombinant inbred mouse strains. |
| Volume: |
25 |
| Issue: |
7-8 |
| Pages: |
569-79 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Beechey C |
| Year: |
1990 |
| Journal: |
Genomics |
| Title: |
Mapping of mouse carbonic anhydrase-3, Car-3: another locus in the homologous region of mouse chromosome 3 and human chromosome 8. |
| Volume: |
6 |
| Issue: |
4 |
| Pages: |
692-6 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Knudsen B |
| Year: |
2003 |
| Journal: |
Genetics |
| Title: |
Using evolutionary rates to investigate protein functional divergence and conservation. A case study of the carbonic anhydrases. |
| Volume: |
164 |
| Issue: |
4 |
| Pages: |
1261-9 |
|
•
•
•
•
•
|
| Publication |
| First Author: |
Yeats C |
| Year: |
2003 |
| Journal: |
BMC Microbiol |
| Title: |
New knowledge from old: in silico discovery of novel protein domains in Streptomyces coelicolor. |
| Volume: |
3 |
|
| Pages: |
3 |
|
•
•
•
•
•
|
| Protein |
| Organism: |
Mus musculus/domesticus |
| Length: |
150
 |
| Fragment?: |
false |
|
•
•
•
•
•
|