ライフサイエンスコーパス: karyogamy

1 clei and their SPBs came together and fused (karyogamy).

2 occur during nuclear proliferation prior to karyogamy.

3 ik1, the kinesin motor that is essential for karyogamy.

4 n mating yeast cells, positioning nuclei for karyogamy.

5 usion during conjugation, a process known as karyogamy.

6 e fusion reactions catalysed by p97, such as karyogamy.

7 ubset of Stel2p-inducible genes required for karyogamy.

8 ientation, nuclear movement and positioning, karyogamy and chromosomal stability, defects also found

9 yces cerevisiae Kinesin-14, is essential for karyogamy and meiosis I but also has specific functions

10 3p in the microtubule-dependent processes of karyogamy and mitosis.

11 ility and function in cell processes such as karyogamy and nuclear migration and positioning in the y

12 In contrast, although karyogamy and nucleolar fusion are apparently normal in

13 formation and telomere clustering occurs in karyogamy and persists throughout the horsetail stage.

14 f the genome remain unreplicated until after karyogamy and subsequent chromosome pairing have taken p

15 that the prophase program senses absence of karyogamy and/or absence of a homolog partner and adjust

16 that is involved in both nuclear fusion, or karyogamy, and mitosis.

17 e data suggest that the fusion of nuclei, or karyogamy, and subsequently somatic homologous recombina

18 The molecular mechanisms controlling karyogamy are poorly understood.

19 This latter event, called karyogamy, can be divided into two distinct steps: the m

20 Bik1p (bilateral karyogamy defect protein) is one of the MAPs required fo

21 letion of BIM1 results in a strong bilateral karyogamy defect, hypersensitivity to benomyl, and aberr

22 nslocation defect but does not alleviate the karyogamy defect.

23 inst the alternative interpretation that the karyogamy defects result as an indirect consequence of t

24 or Mps2 C terminus have SPB duplication and karyogamy defects that are consistent with the aberrant

25 63-1 and sec72Delta, also exhibited moderate karyogamy defects.

26 vel sec63 mutant alleles that display severe karyogamy defects.

27 severe protein translocation defects show no karyogamy defects.

28 proteins (Sec71p and Sec72p) also results in karyogamy defects.

29 nfd1 is also affected in karyogamy during double fertilization.

30 Nuclear movement before karyogamy in eukaryotes is known as pronuclear migration

31 ive growth, whereas it becomes essential for karyogamy in mating cells, explaining the important role

32 4-domain ubiquitous family, as essential for karyogamy in the filamentous fungus Sordaria macrospora,

33 Karyogamy is delayed by >1 h in fus1 mating pairs, possi

34 In wild-type C. cinereus, karyogamy is followed by condensation and alignment of h

35 Given that karyogamy is not supposed to occur until after premeioti

36 Also, in haplobiontic organisms, karyogamy is required to produce the diploid nucleus/cel

37 Karyogamy is the process whereby two haploid nuclei fuse

38 ired for differentiation of fruiting bodies, karyogamy, meiosis, and efficient formation of meiotic p

39 We found that, after karyogamy, microtubule organization changed from a radia

40 These conflicting results suggest that karyogamy might actually precede DNA replication in Pyre

41 ar9 was originally identified as a bilateral karyogamy mutant, in which the two zygotic nuclei remain

42 some alignment, and nuclear migration during karyogamy (nuclear fusion during mating).

43 In angiosperms, karyogamy occurs three times: twice during double fertil

44 Karyogamy, or nuclear fusion, is essential for sexual re

45 al reproduction fails: klp2 Delta,dhc1-d1 in karyogamy, pkl1 Delta,dhc1-d1 in multiple phases of meio

46 motor Kar3p, though known to be required for karyogamy, plays a poorly defined, nonessential role dur

47 amed Ime4 and KAR4 (Inducer of meiosis 4 and Karyogamy protein 4), and Female-lethal (2)d (Fl(2)d) an

48 aromyces cerevisiae required for mitosis and karyogamy, reportedly interacts with Cik1, a nonmotor pr

49 Karyogamy requires both the Sec18p/NSF ATPase and ER/NE

50 nt to microtubule tips, nuclear movement and karyogamy, solely Site2 functions in spindle positioning

51 isiae that is required for the expression of karyogamy-specific genes during mating, for the efficien

52 a putative transcription factor required for karyogamy (the fusion of haploid nuclei during mating) a

53 KAR5 is required for membrane fusion during karyogamy, the process of nuclear fusion during yeast ma

54 Karyogamy, the process of nuclear fusion is required for

55 and rad9-1 nuclei from the meiotic stages of karyogamy through metaphase I, and we determined the pri

56 t mitotic cell cycle is long enough to allow karyogamy to be accomplished successfully.

57 ing nuclear congression during fission yeast karyogamy upon mating of haploid cells.

58 eus closer to the site where cell fusion and karyogamy will occur.