about
Rethinking dog domestication by integrating genetics, archeology, and biogeographyDown-regulation of caveolin-1, a candidate tumor suppressor gene, in sarcomasCaveolin-1 is down-regulated in human ovarian carcinoma and acts as a candidate tumor suppressor geneMutations of the GREAT gene cause cryptorchidismGenetic targeting of relaxin and insulin-like factor 3 receptors in miceReduced androgen receptor expression accelerates the onset of ERBB2 induced breast tumors in female mice.Cryptorchidism in mice with an androgen receptor ablation in gubernaculum testis.Mutations in the insulin-like factor 3 receptor are associated with osteoporosis.Isolation and expression analysis of the canine insulin-like factor 3 gene.Long-Lasting Consequences of Testosterone ExposureINSL3/RXFP2 signaling in testicular descent.Identification of small-molecule agonists of human relaxin family receptor 1 (RXFP1) by using a homogenous cell-based cAMP assay.T222P mutation of the insulin-like 3 hormone receptor LGR8 is associated with testicular maldescent and hinders receptor expression on the cell surface membrane.Novel mutations involving the INSL3 gene associated with cryptorchidism.Identification and optimization of small-molecule agonists of the human relaxin hormone receptor RXFP1.NOTCH1 gain of function in germ cells causes failure of spermatogenesis in male miceSuppression of insulin-like3 receptor reveals the role of β-catenin and Notch signaling in gubernaculum development.Uterine cysts in female mice deficient for caveolin-1 and insulin-like 3 receptor RXFP2The fate of spermatogonial stem cells in the cryptorchid testes of RXFP2 deficient miceInsulin-like 3 signaling is important for testicular descent but dispensable for spermatogenesis and germ cell survival in adult mice.Relaxin increases human endothelial progenitor cell NO and migration and vasculogenesis in miceInsulin-like 3 signalling in testicular descent.Activation of Relaxin Family Receptor 1 from Different Mammalian Species by Relaxin Peptide and Small-Molecule Agonist ML290.INSL3/LGR8 role in testicular descent and cryptorchidism.Conditional deletion of the relaxin receptor gene in cells of smooth muscle lineage affects lower reproductive tract in pregnant mice.Relaxin acts on stromal cells to promote epithelial and stromal proliferation and inhibit apoptosis in the mouse cervix and vagina.Testicular cancer and cryptorchidism.Relaxin and related peptides in male reproduction.Left-sided cryptorchidism in mice with Wilms' tumour 1 gene deletion in gubernaculum testis.Relative roles of the epithelial and stromal tissue compartment(s) in mediating the actions of relaxin and estrogen on cell proliferation and apoptosis in the mouse lower reproductive tract.Relaxin-like peptides in male reproduction - a human perspective.Normal fertility in male mice with deletion of β-catenin gene in germ cells.Estrogen and TCDD influence RLN2 gene activity in estrogen receptor-positive human breast cancer cells.New roles for INSL3 in adults.Insulin-like factor 3 gene mutations in testicular dysgenesis syndrome: clinical and functional characterization.Gene expression profiling in RAS oncogene-transformed cell lines and in solid tumors using subtractive suppression hybridization and cDNA arrays.Normal prostate morphology in relaxin-mutant mice.A missense mutation in LRR8 of RXFP2 is associated with cryptorchidism.Spermatogenesis in cryptorchidism.Protein expression profiling of endometriosis: validation of 2-mm tissue microarrays.
P50
Q28267212-6DA1EEE3-4F2F-4D22-B5EC-0753C6EB3099Q28359685-58726D67-8E5D-4C45-9BB3-3951DF153EA2Q28363368-8E61F2AD-B715-44DC-825F-701E1D7A4A1BQ28507046-3CB1D179-4189-438A-95B8-875F5AE8EF84Q28594942-F7A74026-1240-48AA-91F2-618039C53027Q30419961-F204E4B3-FDA7-4C28-AE0C-C55DE06A54AEQ30421688-16F3837D-7164-4B2F-860B-BA8159F83940Q30439664-C1B56310-90E2-4242-94A1-D90A1438353EQ33187953-780C9E6D-7BE6-4900-9D59-6BD6DB7A499AQ33585078-7030AE91-16B6-4EFF-8287-D3CCCA5D4A72Q34267411-BB367293-ED0A-4A5D-A5FE-BAA786D6DC7AQ34501476-29D50A59-C3F7-481A-82D9-329DAE670DD6Q34559725-DEC233F2-5596-4FD4-83A4-33EF0B7BA9E2Q34619627-94A133BD-AB62-4874-8101-74642A417E53Q34771756-44F387CB-CD86-49CC-AAD1-46B0A8FFC993Q34923727-FFE19C19-A6AA-4355-8021-F5020FEAA09CQ34942943-CA1F315B-B44F-4104-A82A-3AD1B205165AQ35001368-24082363-776E-4402-8D33-EB92B468F982Q35009754-B9EDB505-87B1-4FBC-83DD-21168B900BA0Q35618408-7647A2C6-560D-420B-8422-6B30CD4B138EQ35669250-BEB01CDB-41DE-404F-A7DF-DA3BE4E28CAAQ35893296-4457E5A7-753B-4A39-A82B-F2A8F73643C7Q35960484-BF3B1C61-B5B1-440A-8F40-68D18A53763FQ36037685-8BFE7F45-62C3-4A23-94CA-279690A7A09DQ36277282-9A2BE8E3-82C6-4614-9CAC-2C64C5FA5940Q36578873-4EC417C8-CB7E-4873-8BFB-7B0660C6579FQ36700205-2791A8A5-73FA-4A1F-A0D5-58805F4FAD48Q37045603-70794B6E-DFE5-49C3-B38A-FDADFD10316DQ37284507-F84D1840-A7FC-4109-AC1F-1B8C5847AE0CQ37345765-6E502A8B-8A3E-40AD-AA4D-B2EE96A62AA2Q39033904-22F1BC3A-0E78-4CF4-AB3F-8C770B905E22Q39268750-61CA16B4-84FB-4A1E-9AFA-587554BB3BADQ39856616-63F56E29-322F-4618-86C0-B6A94374FB2EQ39856655-3C9427FE-9472-46E8-AE73-011451A74C04Q40281471-938E0BD2-BB1A-4AF2-BEAD-5D41997BC595Q40717680-75515F7F-097D-43A4-B5D3-AD20E80D729EQ42426476-8C0F71E2-9BE4-43EA-BCB2-335809B0D8F6Q42852067-80957EA5-577A-41B9-BFDB-6D7312550E6EQ44848015-A860AD66-99E2-4D44-AC39-F60FB094B304Q45181674-559B3CCE-E493-4C91-AB84-F400A845B002
P50
description
hulumtues
@sq
researcher
@en
ricercatore
@it
wetenschapper
@nl
հետազոտող
@hy
name
Alexander Agoulnik
@ast
Alexander Agoulnik
@en
Alexander Agoulnik
@es
Alexander Agoulnik
@nl
type
label
Alexander Agoulnik
@ast
Alexander Agoulnik
@en
Alexander Agoulnik
@es
Alexander Agoulnik
@nl
prefLabel
Alexander Agoulnik
@ast
Alexander Agoulnik
@en
Alexander Agoulnik
@es
Alexander Agoulnik
@nl
P214
P244
P106
P1153
6603393500
P21
P214
P244
n2007184006
P31
P496
0000-0001-6587-6845
P735
P7859
lccn-n2007184006