ライフサイエンスコーパス: lactogenic

1 uence is present in all hormones stimulating lactogenic action and absent in all hormones stimulating

2 wth hormone (hGH) stimulates somatogenic and lactogenic actions through the GH and prolactin (PRL) re

3 isrupts hydrophobic interactions and reduces lactogenic activity between 4.7- and 85-fold with little

4 e differential effects indicate that loss of lactogenic activity is not a result of global mis-foldin

5 We propose the loss of lactogenic activity results from disruption of specific

6 Phe44 is a feature necessary for specifying lactogenic activity.

7 isolated from milk and treated with various lactogenic agents in 3D transwell systems.

8 cancerous mammary epithelial cells to become lactogenic and evolve into tumors with diminished potent

9 t this peptide acts as an antagonist of both lactogenic and somatotrophic hGH actions.

10 inding protein, but is also activated by non-lactogenic cytokines in many cell types.

11 Cells expressing SL-1 were unable to undergo lactogenic differentiation and became invasive.

12 s of beta-casein, an established reporter of lactogenic differentiation and milk production.

13 ta suggests that the failure of alveolar and lactogenic differentiation due to the loss of Elf5 is me

14 d LY294002 (PI3K-specific inhibitor) blocked lactogenic differentiation in a dose-dependent manner.

15 ach induced STAT5A activation, expression of lactogenic differentiation markers, and lumen formation

16 ghtened energetic and nutrient demand during lactogenic differentiation of the mammary gland elicits

17 alyses show that anti-RANKL therapy promotes lactogenic differentiation of tumor cells.

18 Wnt1 and Twist can function as inhibitors of lactogenic differentiation, an effect that could contrib

19 ium, caused precocious STAT5a activation and lactogenic differentiation, and increased cell surface E

20 tumorigenesis specifies a tumor phenotype of lactogenic differentiation, suppresses EMT, and diminish

21 ogated induction of WDNM1, another marker of lactogenic differentiation.

22 e mice but displayed hallmarks of precocious lactogenic differentiation.

23 development, we were able to demonstrate its lactogenic function in cultured mammary epithelium from

24 smembrane cleavage impaired STAT5A activity, lactogenic gene expression, and lumen formation.

25 kling, the consequent decline in circulating lactogenic hormone concentrations initiates remodeling o

26 We investigated the role of the lactogenic hormone prolactin (PRL) in the regulation of

27 Treatment with the lactogenic hormone prolactin (PRL) in vitro has been sho

28 The lactogenic hormone prolactin (PRL) transcriptionally inc

29 Lactogenic hormone regulation of beta-casein gene expres

30 Prolactin, a lactogenic hormone, binds to two prolactin receptors seq

31 nstrated that AFAP1 responds to prolactin, a lactogenic hormone, by forming a complex with cSrc and b

32 old and 12.5-fold, respectively, whereas the lactogenic hormone, prolactin (PRL) stimulated a 3.5-fol

33 The lactogenic hormone-induced interaction between the proxi

34 n increased cell proliferation and inhibited lactogenic hormone-mediated differentiation as revealed

35 ck C reduced the response of the promoter to lactogenic hormones 84%.

36 ctivation of signal transduction pathways by lactogenic hormones and cell-substratum interactions act

37 ot functionally differentiate in response to lactogenic hormones despite their organization into thre

38 However, the exact mechanisms by which the lactogenic hormones drive beta cell expansion remain unc

39 hin alveolar lumens; systemically, levels of lactogenic hormones fall.

40 To explore potential roles for lactogenic hormones in human fetal development, we exami

41 The potential role of lactogenic hormones in MS is discussed.

42 GADD153 expression was upregulated by the lactogenic hormones insulin and progesterone and associa

43 duction, lactation, and immune function, the lactogenic hormones likely play roles in tissue differen

44 val, and function and mediated mainly by the lactogenic hormones prolactin (PRL) and placental lactog

45 a transgenic mouse model engineered so that lactogenic hormones stimulate a sustained increase in eI

46 mouse mammary GPT gene is stimulated by the lactogenic hormones, insulin, glucocorticoid, and prolac

47 This study explores the role of lactogenic hormones, prolactin (PRL) and placental lacto

48 In the presence of lactogenic hormones, recombinant expression of caveolin-

49 dered receptor binding for each of the three lactogenic hormones.

50 mber, secretory capacity, and sensitivity to lactogenic hormones.

51 the milk protein beta-casein in response to lactogenic hormones.

52 iates in response to a basement membrane and lactogenic hormones.

53 lveolar PCD even in the presence of systemic lactogenic hormones.

54 ultivation with the combination of the three lactogenic hormones.

55 se was disrupted in the presence of systemic lactogenic hormones: (i) sealing of the teats, (ii) mamm

56 ng of ordered binding to include three human lactogenic hormones: prolactin, growth hormone, and plac

57 be a promising strategy to prolong maternal lactogenic immunity against postweaning infections.

58 for maternal rotavirus vaccination to boost lactogenic immunity and transfer passive antibodies to t

59 be designed using reverse genetics to induce lactogenic immunity in pregnant sows to protect piglets

60 was imaged optically in real time following lactogenic induction.

61 eIF4E abundance in stem/progenitor cells of lactogenic mammary epithelium during successive pregnanc

62 tudies have broad implications for using the lactogenic microenvironment as a paradigm to discover ne

63 l model to study the protective effects of a lactogenic microenvironment on mammary tumor onset and p

64 structures, either free or bound to a single lactogenic or somatotrophic receptor, shows binding is a

65 hGH structure are unique when binding either lactogenic or somatotrophic receptors and they influence

66 Human growth hormone (hGH) binds lactogenic or somatotrophic receptors, creating active h

67 the mammary gland and bestows a differential lactogenic phenotype between #3 mammary glands and the t

68 east cancers, consistent with a constitutive lactogenic phenotype.

69 e to feedback inhibition of prolactin by the lactogenic properties of the hGH transgene.

70 either alanine or leucine partially restored lactogenic receptor binding affinity, which correlated w

71 rophobic side chain of Phe44 is required for lactogenic receptor binding and activation but is unnece

72 on of Phe44 reduced binding affinity for the lactogenic receptor, resulting in a reduced activation.

73 and an obligate mediator of mammopoietic and lactogenic signaling.

74 d into the basolateral side of bMECs without lactogenic treatment, suggesting their local de novo syn