ライフサイエンスコーパス: sperm maturation

1 s that impair spermatogenesis and epididymal sperm maturation.

2 lfur-sulfur bonds during the final stages of sperm maturation.

3 cluding immune defenses, venom toxicity, and sperm maturation.

4 of the initial segment and therefore, normal sperm maturation.

5 whereas TAp73 ensures fertility by enabling sperm maturation.

6 mpared with controls, suggesting compromised sperm maturation.

7 rnover of the mouse Piwi protein MIWI during sperm maturation.

8 the testis is removed from chromatin during sperm maturation.

9 A helicase that is an essential regulator of sperm maturation.

10 pididymal (downstream) pathways required for sperm maturation.

11 ity of a normally formed axoneme occurs with sperm maturation.

12 ve calcineurin to function during epididymal sperm maturation.

13 ely in testis, coincident with the timing of sperm maturation.

14 ing it in the control of ovarian atresia and sperm maturation.

15 iption factor regulating spermatogenesis and sperm maturation.

16 g pattern observed in vivo during epididymal sperm maturation.

17 1 h/day) over a 10-day period, aligning with sperm maturation.

18 llular matrix with roles in host defense and sperm maturation.

19 permatocytes 'primes' post-meiosis steps for sperm maturation.

20 ects on spermiogenesis, including incomplete sperm maturation and a massive reduction in sperm number

21 n implicated in various processes, including sperm maturation and cancer progression.

22 and epididymis, which probably contribute to sperm maturation and capacitation, is established during

23 lts in defective histone-protamine exchange, sperm maturation and chromatin organization.

24 d sperm PP2B are essential during epididymal sperm maturation and during fertilization.

25 re essential in development and required for sperm maturation and fertility in Drosophila.

26 Proteins associated with sperm maturation and fertilization were identified, incl

27 epididymal epithelial cells responsible for sperm maturation and find 7282 differentially H3K27me3 b

28 rylation that occurs late in the sequence of sperm maturation and for a negative feedback control of

29 e that ASM activity plays a critical role in sperm maturation and function, and a basis for similar s

30 ete reproductive tract proteins required for sperm maturation and function, like the mammalian epidid

31 demonstrate the importance of ASM for normal sperm maturation and function.

32 the elimination of residual cytoplasm during sperm maturation and had increased staining for the casp

33 nderthals and Denisovans in genes related to sperm maturation and immunity.

34 regulates epididymal function for successful sperm maturation and male fertility.

35 bulin polyglutamylation that is required for sperm maturation and motility and may be relevant for ma

36 Loss of PP2B results in impaired epididymal sperm maturation and motility.

37 s showed that they are both processed during sperm maturation and present on mature sperm.

38 ididymal lumen and has proposed functions in sperm maturation and protection.

39 status-specific differences in mating rates, sperm maturation and sperm competition.

40 ogical amyloid matrix with putative roles in sperm maturation and sperm protection.

41 tions as transition zone for post-testicular sperm maturation and storage and faces contrasting immun

42 n which luminal acidification is crucial for sperm maturation and storage, these projections contain

43 which luminal acidification is critical for sperm maturation and storage, we now report a novel path

44 n which luminal acidification is crucial for sperm maturation and storage, we now report that modulat

45 ignaling may influence fluid handling during sperm maturation and storage.

46 ole of NCOA5 in the regulation of epididymal sperm maturation and suggest that NCOA5 deficiency could

47 including pathogen defense, immune evasion, sperm maturation, and cancer progression.

48 lved in immunity and antimicrobial defences, sperm maturation, and fertilisation, revealing a functio

49 An acidic luminal pH is involved in sperm maturation, and in maintaining sperm in an immotil

50 its dietary regulation during posttesticular sperm maturation, and they also link tRNA fragments to r

51 in renal pH homeostasis, bone resorption and sperm maturation, and various disease processes, includi

52 unknown role for phosphoinositides in normal sperm maturation beyond their previously characterized i

53 ive epididymal differentiation and deficient sperm maturation but can be restored by NICOL expression

54 Thus, EVs as a normal process in sperm maturation, can also perform roles in intergenerat

55 Ca(2+) influx and processes associated with sperm maturation, collectively known as capacitation.

56 Chromatin remodeling during sperm maturation could erase epigenetic landmarks on the

57 productive tract and have been implicated in sperm maturation events that may contribute to fertiliza

58 ed for implantation and are not required for sperm maturation events that permit fertilization and th

59 fertilin beta is processed separately during sperm maturation in the epididymis.

60 m ability to fertilize the egg by regulating sperm maturation in the female reproductive tract and by

61 al of bulk cytoplasm in spermatids and block sperm maturation in vivo, causing male sterility.

62 Post-testicular sperm maturation, in which sperm centrioles found in the

63 m early mitotic divisions to later stages of sperm maturation, individualization, and motility.

64 Across species, sperm maturation involves the dramatic reconfiguration o

65 essential role of this kinase in epididymal sperm maturation involving cSrc extracellular traffickin

66 Epididymal sperm maturation is regulated by lumicrine signalling pa

67 Epididymis, playing important roles in sperm maturation, is a typical organ of this type, which

68 P-generating enzyme previously implicated in sperm maturation, is expressed in developing rat axons a

69 nes regulating post-meiotic events including sperm maturation, motility and fertilization.

70 All subsequent processes of sperm maturation occur in the complete absence of transc

71 Following DNA compaction, further sperm maturation occurs in the epididymis.

72 myloid structure that may carry out roles in sperm maturation or maintenance of the luminal milieu an

73 n mechanism might, therefore, result in poor sperm maturation, premature motility and infertility.

74 range of substrates reduced by TXNRD3 during sperm maturation, presumably as a part of sperm quality

75 During sperm maturation, the anterior head membranes undergo a

76 During epididymal sperm maturation, the lipid content of the sperm membran

77 A late step in sperm maturation therefore requires the physical resolut

78 mline-specific actin structures critical for sperm maturation, via a unique N-terminal tail.