Search research articles
Contact Us
Filters
Showing results (51-60 of 79) with videos related to
Page
of 8
Sort By:
Journal of Bacteriology
|
November 1, 1992
Phenotypes of sphingolipid-dependent strains of Saccharomyces cerevisiae
J L Patton, B Srinivasan, R C Dickson, et al.
Journal of Bacteriology
|
August 1, 1970
Polar lipids of Chromatium strain D grown at different light intensities
S Steiner, J C Burnham, S F Conti, et al.
Molecular and Cellular Biology
|
May 1, 1990
Isolation of mutant Saccharomyces cerevisiae strains that survive without sphingolipids
R C Dickson, G B Wells, A Schmidt, et al.
Journal of Hand Surgery (Edinburgh, Scotland)
|
August 1, 1993
Intrinsic reinnervation--myth or reality?
R L Lester, P J Smith, G Mott, et al.
Current Genetics
|
January 25, 2002
Elevation of endogenous sphingolipid long-chain base phosphates kills Saccharomyces cerevisiae cells
X Zhang, M S Skrzypek, R L Lester, et al.
The Journal of Biological Chemistry
|
January 15, 1993
Mutant strains of Saccharomyces cerevisiae lacking sphingolipids synthesize novel inositol glycerophospholipids that mimic sphingolipid structures
R L Lester, G B Wells, G Oxford, et al.
Biochemistry
|
August 22, 1978
Structure of a major glycophosphoceramide from tobacco leaves, PSL-I: 2-deoxy-2-acetamido-D-glucopyranosyl(alpha1 leads to 4)-D-glucuronopyranosyl(alpha1 leads to 2)myoinositol-1-O-phosphoceramide
T C Hsieh, K Kaul, R A Laine, et al.
Analytical Biochemistry
|
January 15, 1981
Separation of dolichylpyrophosphoryloligosaccharides by liquid chromatography
G B Wells, S J Turco, B A Hanson, et al.
The Journal of Biological Chemistry
|
October 15, 1993
A suppressor gene that enables Saccharomyces cerevisiae to grow without making sphingolipids encodes a protein that resembles an Escherichia coli fatty acyltransferase
M M Nagiec, G B Wells, R L Lester, et al.
Journal of Bacteriology
|
February 11, 1999
Analysis of phosphorylated sphingolipid long-chain bases reveals potential roles in heat stress and growth control in Saccharomyces
M S Skrzypek, M M Nagiec, R L Lester, et al.
Page
of 8
Search research articles
Search
Showing results (51-60 of 79) with videos related to
Sort By:
Page
of 8
Journal of Bacteriology
|
November 1, 1992
Phenotypes of sphingolipid-dependent strains of Saccharomyces cerevisiae
J L Patton, B Srinivasan, R C Dickson, et al.
Journal of Bacteriology
|
August 1, 1970
Polar lipids of Chromatium strain D grown at different light intensities
S Steiner, J C Burnham, S F Conti, et al.
Molecular and Cellular Biology
|
May 1, 1990
Isolation of mutant Saccharomyces cerevisiae strains that survive without sphingolipids
R C Dickson, G B Wells, A Schmidt, et al.
Journal of Hand Surgery (Edinburgh, Scotland)
|
August 1, 1993
Intrinsic reinnervation--myth or reality?
R L Lester, P J Smith, G Mott, et al.
Current Genetics
|
January 25, 2002
Elevation of endogenous sphingolipid long-chain base phosphates kills Saccharomyces cerevisiae cells
X Zhang, M S Skrzypek, R L Lester, et al.
The Journal of Biological Chemistry
|
January 15, 1993
Mutant strains of Saccharomyces cerevisiae lacking sphingolipids synthesize novel inositol glycerophospholipids that mimic sphingolipid structures
R L Lester, G B Wells, G Oxford, et al.
Biochemistry
|
August 22, 1978
Structure of a major glycophosphoceramide from tobacco leaves, PSL-I: 2-deoxy-2-acetamido-D-glucopyranosyl(alpha1 leads to 4)-D-glucuronopyranosyl(alpha1 leads to 2)myoinositol-1-O-phosphoceramide
T C Hsieh, K Kaul, R A Laine, et al.
Analytical Biochemistry
|
January 15, 1981
Separation of dolichylpyrophosphoryloligosaccharides by liquid chromatography
G B Wells, S J Turco, B A Hanson, et al.
The Journal of Biological Chemistry
|
October 15, 1993
A suppressor gene that enables Saccharomyces cerevisiae to grow without making sphingolipids encodes a protein that resembles an Escherichia coli fatty acyltransferase
M M Nagiec, G B Wells, R L Lester, et al.
Journal of Bacteriology
|
February 11, 1999
Analysis of phosphorylated sphingolipid long-chain bases reveals potential roles in heat stress and growth control in Saccharomyces
M S Skrzypek, M M Nagiec, R L Lester, et al.
Page
of 8