Mark Ptashne | Academic Influence

Mark Ptashne's AcademicInfluence.com Rankings

Mark Ptashne

Biology

#234

World Rank

#424

Historical Rank

#137

USA Rank

Molecular Biology

#53

World Rank

#54

Historical Rank

#38

USA Rank

Biochemistry

#92

World Rank

#120

Historical Rank

#53

USA Rank

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Biology

Mark Ptashne's Degrees

Bachelors Chemistry Columbia University

Why Is Mark Ptashne Influential?

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According to Wikipedia, Mark Ptashne is a molecular biologist. He is the Ludwig Chair of Molecular Biology at Memorial Sloan–Kettering Cancer Center in New York City. Ptashne grew up in Chicago. He earned his undergraduate degree at Reed College in Portland, Oregon in 1961 and his PhD from Harvard in 1968, after which he joined the faculty of Harvard. He was made professor there in 1971 and became chair of the Department of Biochemistry and Molecular Biology in 1980. In 1993 he was awarded an endowed chair, and in 1997 he left Harvard for MSK.

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Mark Ptashne's Published Works

Number of citations in a given year to any of this author's works

Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author

Published Works

How eukaryotic transcriptional activators work (1988) (1537)
GAL4-VP16 is an unusually potent transcriptional activator (1988) (1232)
Transcriptional activation by recruitment (1997) (1165)
A Genetic Switch (1986) (794)
Deletion analysis of GAL4 defines two transcriptional activating segments (1987) (778)
Gene regulation by proteins acting nearby and at a distance (1986) (741)
Vectors bearing a hybrid trp-lac promoter useful for regulated expression of cloned genes in Escherichia coli. (1983) (700)
Specific DNA binding of GAL4, a positive regulatory protein of yeast (1985) (654)
A new class of yeast transcriptional activators (1987) (646)
DNA recognition by GAL4: structure of a protein-DNA complex (1992) (633)
Negative effect of the transcriptional activator GAL4 (1988) (619)
A eukaryotic transcriptional activator bearing the DNA specificity of a prokaryotic repressor (1985) (614)
Separation of DNA binding from the transcription-activating function of a eukaryotic regulatory protein. (1986) (568)
A Genetic Switch, Phage Lambda Revisited (2004) (537)
A vector for expressing GAL4(1-147) fusions in mammalian cells. (1989) (513)
GAL4 activates transcription in Drosophila (1988) (488)
Activators and targets (1990) (451)
Recognition of a DNA operator by the repressor of phage 434: a view at high resolution (1988) (448)
Genes and Signals (2001) (428)
Fusion of Escherichia coli lacZ to the cytochrome c gene of Saccharomyces cerevisiae. (1981) (407)
Mechanism of action of the lexA gene product. (1981) (367)
How the λ repressor and cro work (1980) (365)
On the use of the word ‘epigenetic’ (2007) (361)
λ Repressor and cro—components of an efficient molecular switch (1981) (359)
Saccharomyces cerevisiae GAL1-GAL10 divergent promoter region: location and function of the upstream activating sequence UASG (1984) (343)
Cooperative binding of λ repressors to sites separated by integral turns of the DNA helix (1986) (335)
Autoregulation and function of a repressor in bacteriophage lambda. (1976) (332)
A mechanism for synergistic activation of a mammalian gene by GAL4 derivatives (1990) (328)
A genetic switch : phage λ and higher organisms (1992) (327)
The carboxy-terminal 30 amino acids of GAL4 are recognized by GAL80 (1987) (309)
Use of lacZ fusions to delimit regulatory elements of the inducible divergent GAL1-GAL10 promoter in Saccharomyces cerevisiae (1984) (305)
Repressor structure and the mechanism of positive control (1983) (291)
Structure of the represser–operator complex of bacteriophage 434 (1987) (288)
A unified nomenclature for protein subunits of mediator complexes linking transcriptional regulators to RNA polymerase II. (2004) (280)
Contact with a component of the polymerase II holoenzyme suffices for gene activation (1995) (275)
Construction of plasmids carrying the cI gene of bacteriophage lambda. (1976) (267)
Interactions between DNA-bound repressors govern regulation by the λ phage repressor (1979) (266)
An amino-terminal fragment of GAL4 binds DNA as a dimer. (1989) (266)
GAL4 activates gene expression in mammalian cells (1988) (266)
Amino terminus of the yeast GAL4 gene product is sufficient for nuclear localization. (1984) (250)
Mutants of GAL4 protein altered in an activation function (1987) (242)
Transcription in yeast activated by a putative amphipathic α helix linked to a DNA binding unit (1987) (238)
Gene regulation at the right operator (OR) of bacteriophage lambda. II. OR1, OR2, and OR3: their roles in mediating the effects of repressor and cro. (1980) (235)
An HMG-like protein that can switch a transcriptional activator to a repressor (1994) (232)
GAL4 derivatives function alone and synergistically with mammalian activators in vitro (1988) (229)
How different eukaryotic transcriptional activators can cooperate promiscuously (1990) (221)
An activator target in the RNA polymerase II holoenzyme. (1998) (211)
Gene regulation at the right operator (OR) bacteriophage lambda. I. OR3 and autogenous negative control by repressor. (1980) (208)
Effect of non-contacted bases on the affinity of 434 operator for 434 repressor and Cro (1987) (200)
Specific Binding of the λ Phage Repressor to λ DNA (1967) (193)
The lambda repressor contains two domains. (1979) (191)
Quantitation of putative activator‐target affinities predicts transcriptional activating potentials. (1996) (190)
Independent recruitment in vivo by Gal4 of two complexes required for transcription. (2003) (186)
Cooperative DNA binding of the yeast transcriptional activator GAL4. (1988) (185)
A bacterial repressor protein or a yeast transcriptional terminator can block upstream activation of a yeast gene (1984) (184)
Improved methods for maximizing expression of a cloned gene: a bacterium that synthesizes rabbit β-globin (1980) (183)
Chromatin components as part of a putative transcriptional repressing complex. (1998) (182)
A RSC/Nucleosome Complex Determines Chromatin Architecture and Facilitates Activator Binding (2010) (178)
Determinants of binding-site specificity among yeast C6 zinc cluster proteins. (1993) (178)
Epigenetics: Core misconcept (2013) (177)
Inhibition of Eukaryotic DNA Replication by Geminin Binding to Cdt1 (2000) (176)
Recognition sequences of repressor and polymerase in the operators of bacteriophage lambda (1975) (176)
Generating yeast transcriptional activators containing no yeast protein sequences (1991) (173)
ISOLATION OF THE lambda PHAGE REPRESSOR. (1967) (167)
Regulation of transcription: from lambda to eukaryotes. (2005) (166)
The lexA gene product represses its own promoter. (1980) (161)
Structure of a phage 434 Cro/DNA complex (1988) (159)
Activation of yeast polymerase II transcription by herpesvirus VP16 and GAL4 derivatives in vitro (1989) (154)
Activation of gene expression by small molecule transcription factors. (2000) (152)
Yeast activators stimulate plant gene expression (1988) (150)
Telomere looping permits gene activation by a downstream UAS in yeast (2001) (149)
A Genetic Switch: Gene Control and Phage Lambda (1986) (145)
Converting a eukaryotic transcriptional inhibitor into an activator (1988) (139)
Changing the binding specificity of a represser by redesigning an α-helix (1985) (135)
GAL11P: A yeast mutation that potentiates the effect of weak GAL4-derived activators (1990) (132)
Cleavage of the lambda and P22 repressors by recA protein. (1982) (131)
RNA Polymerase II Holoenzyme Recruitment Is Sufficient to Remodel Chromatin at the Yeast PHO5 Promoter (1997) (130)
DNA loops induced by cooperative binding of λ repressor (1986) (126)
Gene activation by recruitment of the RNA polymerase II holoenzyme. (1996) (126)
Mechanism of action of the cro protein of bacteriophage lambda. (1978) (122)
A potent GAL4 derivative activates transcription at a distance in vitro. (1990) (120)
A general method for maximizing the expression of a cloned gene. (1979) (119)
Activator Control of Nucleosome Occupancy in Activation and Repression of Transcription (2008) (117)
A phage repressor–operator complex at 7 Å resolution (1985) (117)
Maximizing gene expression on a plasmid using recombination in vitro (1978) (112)
DNA sequence preferences of GAL4 and PPR1: how a subset of Zn2 Cys6 binuclear cluster proteins recognizes DNA (1996) (111)
Regulatory functions of the λ repressor reside in the amino-terminal domain (1979) (110)
Substituting an α-helix switches the sequence-specific DNA interactions of a repressor (1984) (107)
Sequence of a represser-binding site in the DNA of bacteriophage λ (1974) (107)
The λ and 434 Phage Repressors (1970) (105)
Lambda repressor turns off transcription of its own gene. (1975) (98)
Rescue of bicoid mutant Drosophila embryos by Bicoid fusion proteins containing heterologous activating sequences (1989) (97)
The operators controlled by the lambda phage repressor. (1968) (96)
Cooperative binding of lambda repressors to sites separated by integral turns of the DNA helix. (1986) (95)
DNA twisting and the affinity of bacteriophage 434 operator for bacteriophage 434 repressor. (1988) (94)
Multiple repressor binding at the operators in bacteriophage lambda. (1973) (93)
A single glutamic acid residue plays a key role in the transcriptional activation function of lambda repressor (1989) (92)
A new-specificity mutant of 434 repressor that defines an amino acid–base pair contact (1987) (91)
Design of artificial transcriptional activators with rigid poly-L-proline linkers. (2002) (91)
Gene regulation at the right operator (OR) of bacteriophage λ: III. λ Repressor directly activates gene transcription (1980) (90)
Chip interacts with diverse homeodomain proteins and potentiates bicoid activity in vivo. (2000) (90)
Expression of the human fibroblast interferon gene in Escherichia coli. (1980) (89)
How the lambda repressor and cro work. (1980) (83)
Mutant lambda phage repressor with a specific defect in its positive control function. (1982) (81)
New eukaryotic transcriptional repressers (1993) (79)
Delineation of two functional regions of transcription factor TFIIB. (1993) (79)
Interactions between an HMG-1 protein and members of the Rel family. (1999) (78)
Transcription in yeast activated by a putative amphipathic alpha helix linked to a DNA binding unit. (1987) (78)
HSP90/70 chaperones are required for rapid nucleosome removal upon induction of the GAL genes of yeast (2008) (72)
Transcriptional Activation by Oct4 Is Sufficient for the Maintenance and Induction of Pluripotency (2012) (71)
Principles of a switch. (2011) (70)
How λ repressor and λ Cro distinguish between OR1 and OR3 (1986) (69)
Active Form of Two Coliphage Repressors (1970) (68)
Homologous interactions of λ repressor and λ Cro with the λ operator (1986) (68)
Towards a minimal motif for artificial transcriptional activators. (2001) (68)
Effect of drugs on discharge characteristics of chronic epileptogenic lesions (1959) (68)
Cocrystals of the DNA-binding domain of phage 434 repressor and a synthetic phage 434 operator. (1984) (66)
Novel properties of a restriction endonuclease isolated from Haemophilus parahaemolyticus. (1976) (66)
Regulated expression of an extrachromosomal human beta-interferon gene in mouse cells. (1982) (63)
Effect of Diphenylhydantion on Peripheral Nerve (1958) (62)
Interaction at a distance between λrepressers disrupts gene activation (1988) (61)
GAL4 is phosphorylated as a consequence of transcriptional activation. (1991) (60)
Mutations that increase the activity of a transcriptional activator in yeast and mammalian cells. (1990) (60)
Imposing specificity by localization: mechanism and evolvability (1998) (60)
Transcriptional activating regions target a cyclin-dependent kinase (2002) (58)
A genetic switch in a bacterial virus. (1982) (57)
A transcriptional activating region with two contrasting modes of protein interaction. (1998) (56)
Regulation of damage-inducible genes in Escherichia coli. (1982) (56)
How gene activators work. (1989) (56)
Transcriptional activation by artificial recruitment in yeast is influenced by promoter architecture and downstream sequences. (1999) (55)
Faddish Stuff: Epigenetics and the Inheritance of Acquired Characteristics (2013) (55)
Promoters are in the operators in phage lambda (1974) (54)
Structure and mobility of the PUT3 dimer (1997) (54)
Interactions between DNA-bound repressors govern regulation by the lambda phage repressor. (1979) (52)
Binding reactions: epigenetic switches, signal transduction and cancer (2009) (49)
Structure of the λ Operators (1973) (49)
Overproduction and single-step purification of GAL4 fusion proteins from Escherichia coli. (1993) (49)
Multiple mechanisms mediate glucose repression of the yeast GAL1 gene. (1992) (49)
Interactions of a Rel protein with its inhibitor. (1995) (49)
NH2-terminal arm of phage lambda repressor contributes energy and specificity to repressor binding and determines the effects of operator mutations. (1985) (49)
Recruitment of the transcriptional machinery through GAL11P: structure and interactions of the GAL4 dimerization domain. (2001) (48)
Turning λ Cro into a transcriptional activator (1988) (48)
Operator sequences of bacteriophages P22 and 21. (1980) (47)
An effect of DNA sequence on nucleosome occupancy and removal (2011) (47)
REPLICATION AND HOST MODIFICATION OF DNA TRANSFERRED DURING BACTERIAL MATING. (1965) (46)
Responses of Four Yeast Genes to Changes in the Transcriptional Machinery Are Determined by Their Promoters (2002) (46)
Mutants of the catabolite activator protein of Escherichia coli that are specifically deficient in the gene-activation function. (1987) (45)
Isolation of the 434 Phage Repressor (1969) (45)
Imposing Specificity on Kinases (2003) (45)
Expression of a VHCκ chimaeric protein in mouse myeloma cells (1984) (44)
Sites of contact between λ operators and λ repressor (1977) (43)
Synthesis of simian virus 40 t antigen in Escherichia coli. (1979) (43)
Structure of the operator-binding domain of bacteriophage lambda repressor: implications for DNA recognition and gene regulation. (1983) (43)
Effect of diphenylhydantoin on peripheral nerve. (1958) (43)
Transcriptional activation by artificial recruitment in mammalian cells. (1999) (41)
The Chemistry of Regulation of Genes and Other Things (2014) (41)
Ethylation interference and X-ray crystallography identify similar interactions between 434 repressor and operator (1985) (41)
Site-directed mutagenesis of an invariant amino acid residue at the variable-diversity segments junction of an antibody. (1986) (40)
In vitro Repression of RNA Synthesis by Purified λ Phage Repressor (1971) (40)
RNA sequences that work as transcriptional activating regions. (2003) (39)
Construction of overproducers of the bacteriophage 434 repressor and cro proteins. (1981) (38)
DNA binding is not sufficient for nuclear localization of regulatory proteins in Saccharomyces cerevisiae (1986) (38)
Control of transcription by the bacteriophage P22 repressor. (1982) (38)
Activation of transcription in vitro by recruitment of the yeast RNA polymerase II holoenzyme. (1998) (38)
A technique for expressing eukaryotic genes in bacteria. (1980) (37)
DNA loops induced by cooperative binding of lambda repressor. (1986) (37)
No strict alignment is required between a transcriptional activator binding site and the "TATA box" of a yeast gene. (1988) (37)
Specific binding of the lambda phage repressor to lambda DNA. (1967) (37)
Nucleosomes and the accessibility problem. (2011) (36)
Genetics of Virulence (1971) (34)
An artificial transcriptional activating region with unusual properties. (2000) (34)
Completed DNA sequences and organization of repressor-binding sites in the operators of phage lambda. (1977) (32)
Lambda's Switch: Lessons from a Module Swap (2006) (31)
Gene transcription by recruitment. (1998) (31)
Control elements in the DNA of bacteriophage lambda. (1974) (31)
Gene regulation at the right operator (OR) of bacteriophage lambda. III. lambda repressor directly activates gene transcription. (1980) (31)
Transcription initiation: imposing specificity by localization. (2001) (30)
Changing the binding specificity of a repressor by redesigning an alpha-helix. (1985) (30)
A repressor heterodimer binds to a chimeric operator. (1988) (29)
An Open Letter to Elias Zerhouni (2005) (29)
Activation of transcription by the bacteriophage 434 repressor. (1986) (28)
THE DETACHMENT AND MATURATION OF CONSERVED LAMBDA PROPHAGE DNA. (1965) (28)
Regulated recruitment and cooperativity in the design of biological regulatory systems (2003) (27)
OCT4 and SOX2 Work as Transcriptional Activators in Reprogramming Human Fibroblasts. (2017) (27)
A bacterial repressor protein or a yeast transcriptional terminator can block upstream activation of a yeast gene. (1985) (24)
Telomere Looping Permits Repression “at a Distance” in Yeast (2002) (22)
Proteolytic Instability and the Action of Nonclassical Transcriptional Activators (2010) (22)
A target essential for the activity of a nonacidic yeast transcriptional activator (2002) (21)
Signal transduction. Imposing specificity on kinases. (2003) (21)
Transcription: A Mechanism for Short-Term Memory (2008) (20)
Substituting an alpha-helix switches the sequence-specific DNA interactions of a repressor. (1984) (19)
A DNA operator-repressor system. (1976) (18)
Mechanism of action of the cro protein of bacteriophage X ( X repressor / cI / operators / transcription / dimethyl sulfate ) (18)
Imposing specificity by localization: mechanism and evolvability (1998) (17)
Questions over the scientific basis of epigenome project (2010) (17)
P22 repressor mutants deficient in co‐operative binding and DNA loop formation. (1989) (17)
Sequence of a repressor-binding site in the DNA of bacteriophage lamda. (1974) (17)
An α-helix determines the DNA-binding specificity of a repressor (1986) (17)
Polycomb Responds to Low Levels of Transcription. (2017) (17)
λ Repressor Function and Structure (1980) (17)
Control of gene transcription: An outline (1997) (17)
Chapter 11 Repressor and Its Action (1971) (16)
A variant of lambda repressor with an altered pattern of cooperative binding to DNA sites. (1995) (16)
Transcriptional activating regions target attached substrates to a cyclin-dependent kinase. (2005) (16)
The TBP-Inhibitory Domain of TAF145 Limits the Effects of Nonclassical Transcriptional Activators (2002) (15)
How lambda repressor and lambda Cro distinguish between OR1 and OR3. (1986) (14)
DNA-binding proteins (1984) (14)
Regulatory functions of the lambda repressor reside in the amino-terminal domain. (1979) (14)
The X repressor contains two domains ( scanning calorimetry / papain digestion / oligomerization / DNA binding ) (12)
Interaction at a distance between lambda repressors disrupts gene activation. (1988) (12)
Regulation of a mammalian gene bearing a CpG island promoter and a distal enhancer. (2013) (12)
Nucleosome Avidities and Transcriptional Silencing in Yeast (2015) (12)
Changing Epstein-Barr viral ZEBRA protein into a more powerful activator enhances its capacity to disrupt latency. (1993) (11)
Synthesis in Escherichia coli of human adenovirus type 12 transforming proteins encoded by early region 1A 13S mRNA and 12S mRNA. (1984) (10)
Homologous interactions of lambda repressor and lambda Cro with the lambda operator. (1986) (10)
Activation of the Gal1 Gene of Yeast by Pairs of `Non-Classical' Activators (2004) (10)
Activation of the Gal1 Gene of Yeast by Pairs of 'Non-Classical' Activators (2004) (10)
The activation defect of a λcI positive control mutant (1997) (9)
Chapter 12 Regulation of Repressor Synthesis (1971) (8)
Expression of a VHC kappa chimaeric protein in mouse myeloma cells. (1984) (8)
Turning lambda Cro into a transcriptional activator. (1988) (8)
Recognition of DNA sequences by the repressor of bacteriophage 434. (1988) (7)
Structure of the lambda operators. (1973) (6)
(Re)Reading The Origin (2009) (6)
Genetic repressors. (1970) (5)
The activation defect of a lambda cI positive control mutant. (1997) (5)
Two “what if” experiments (2004) (5)
Repressors (2007) (5)
The Behavior of Strong and Weak Centromeres at Second Anaphase of Drosophila Melanogaster. (1960) (5)
(Re)Reading The Origin (2009) (4)
35 GAL11, GAL11P, and the Action of GAL4 (1992) (4)
Sites of contact between lambda operators and lambda repressor. (1977) (4)
Corrigendum: A bacterial represser protein or a yeast transcriptional terminator can block upstream activation of a yeast gene (1985) (4)
Regulated expression of an extrachromosomal human p-interferon gene in mouse cells ( interferon induction / double-stranded RNA / bovine papilloma virus vector / DNA-mediated gene transfer / transcript mapping ) (4)
Repressor turns off transcription of its own gene ( autogenous control / restriction endonuclease fragment / DNA sequence / promoter mutation / transcription ) (3)
TheXrepressor contains twodomains (1979) (3)
THE OPERATORS CONTROLLED BY THE X PHAGE REPRESSOR (3)
On speaking, writing and inspiration (2007) (3)
A genetic switch : gene control and phage λ [i.e. lambda] (1987) (3)
1997 Albert Lasker Award for Basic Medical Research. Control of gene transcription: an outline. (1997) (3)
Isolation of the λ and 434 Phage Repressors (1971) (3)
Repressor, operators, and promoters in bacteriophage lambda. (1973) (3)
STRUCTURE AND MOBILITY OF THE PUT3 DIMER: A DNA PINCER, NMR, 13 STRUCTURES (1997) (3)
Francois Jacob 1920–2013 (2014) (2)
How Zebra, A Weak Transactivator, Exerts Strong Biologic Effects (1991) (2)
Francois Jacob (1920-2013) (2013) (2)
In vitro repression of RNA synthesis by purified lambda phage repressor. (1971) (2)
A technique for expressing eukaryotic genes in bacteria. 1980. (1992) (2)
Saccharomyces cerevisiae GALJ-GALJODivergent Promoter Region: Location andFunction oftheUpstreamActivating Sequence UASG (1984) (2)
Mutants of the catabolite activator protein of Escherichia coil that are specifically deficient in the gene-activation function ( 1 acZ fusions / transcription in vitro / protein-protein interaction / RNA polymerase ) (1)
Site-directed mutagenesis of an invariant amino acid residue at the variable-diversity segments junction of an antibody ( p-azobenzenearsonate / transfection / antgen bindlg / affilty / idiotype ) (1)
The "sunday seminar". (1976) (1)
Recognition of DNA sequences by the repressor and Cro proteins of bacteriophage 434 (1988) (1)
Multiple Repressor Binding attheOperators inBacteriophage x (1973) (1)
Moscow genetics congress. (1978) (1)
Epoxide to olefin : a novel biotransformation in the rumen (2005) (1)
Modularity of eukaryotic transcription activators (2003) (1)
Chapter 8. Phage Repressors (2008) (0)
Patents and literature (1983) (0)
A Unified Nomenclature for Protein Subunits of Mediator Complexes Conserved from Fungi to Humans: Med6/pmc5/arc/ Drip33/trap32, Med7/arc/drip/trap34/crsp33, Linking Transcriptional Regulators to Rna Polymerase Ii Arc/crsp/drip150/trap170, Soh1/trap18 (note That Soh1 Has Not Been yet Identified in Pu (0)
Gene Control by the Lambda Phage Repressor (1978) (0)
Always talking to some purpose (2001) (0)
On learning to write (2007) (0)
Alfred P. Sloan, Jr. Prize. Gene regulation. (1991) (0)
Political discussions at gordon conference. (1971) (0)
Political Discussions at Gordon Conference (1971) (0)
Phage repressors. In: strategy of the viral genome. (1971) (0)
TRANSCRIPTIONAL AND TRANSLATIONAL (?) CONTROL OF THE λ REPRESSOR GENE (cI) (1976) (0)
optimal production of polypeptides (1981) (0)
NH 2-terminal arm of phage X repressor contributes energy and specificity to repressor binding and determines the effects of operator mutations ( NH 2-terminal deletions / protein overproduction / ATA initiation codon / front-side and backside contacts ) (0)
Baltimore's unanswered questions (1991) (0)
A Highly Personal Perspective (2001) (0)
Obituary: Ira Herskowitz (1946–2003) (2003) (0)
Regulation der Genexpression durch DNA-bindende Proteine (1989) (0)
Regulation of Transcription of Genes [Abstract Only] (1995) (0)
Imposing specificity by regulated localization (abstract only) (2001) (0)
Letter from Mark Ptashne to Joshua Lederberg (1959) (0)
7 – Gene Control by the λ Phage Repressor (1978) (0)
1964 Gordon Research Conference on Nucleic Acids (2008) (0)
Unglycosylated human fibroblast interferon and a method for manufacturing the same (1981) (0)
Solution nmr structure of the dimerization domain of the yeast transcriptional activator Gal4 (residues 50-106) (2001) (0)
How the phage lambda repressor and cro work (1980) (0)
Geneva Biomedical Research Institute (1998) (0)
Final report [on $gamma$-phage repressor] (1974) (0)
Regulation der Transkription in Eukaryoten und Prokaryoten: ein gemeinsamer Mechanismus (1989) (0)
Repressor and h Cro Distinguish etween 0,l and 0,3 (1986) (0)
Horace Judson (1931–2011) (2011) (0)
Gene regulation (2020) (0)
Molecular mechanisms of mutagenesis and carcinogenesis. Final report, November 1, 1978-October 31, 1979 (1980) (0)
The Detachment and Maturation of Conserved Lambda Prophage DNA (1989) (0)

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