R. John Ellis

Q: What Schools Are Affiliated With R. John Ellis

R. John Ellis is affiliated with the following schools: University of Warwick, Imperial College London, King's College London

R. John Ellis's AcademicInfluence.com Rankings

R. John Ellis

Physics

#4187

World Rank

#5796

Historical Rank

Particle Physics

#207

World Rank

#221

Historical Rank

physics Degrees

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Physics

Why Is R. John Ellis Influential?

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According to Wikipedia, Reginald John Ellis is a British scientist. Early life and education Ellis was educated at Highbury Grammar School, London. He studied at King's College, London and obtained a BSc degree in 1956 and PhD in 1960, for thesis research on the enzymology of transamination. He was supervised by Professor D. D. Davies.

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R. John Ellis'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

Macromolecular crowding: obvious but underappreciated. (2001) (1919)
Homologous plant and bacterial proteins chaperone oligomeric protein assembly (1988) (1213)
Macromolecular crowding: an important but neglected aspect of the intracellular environment. (2001) (983)
Molecular Chaperones (1993) (821)
Cell biology: Join the crowd (2003) (741)
The most abundant protein in the world (1979) (622)
Effects of macromolecular crowding on protein folding and aggregation (1999) (492)
Molecular chaperones: proteins essential for the biogenesis of some macromolecular structures. (1989) (450)
Protein aggregation in crowded environments (2006) (426)
Chloroplast Proteins: Synthesis, Transport, and Assembly (1981) (424)
Synthesis and transport of the small subunit of chloroplast ribulose bisphosphate carboxylase (1978) (392)
The Transport of Proteins into Chloroplasts (1986) (362)
Principles of protein folding in the cellular environment. (1999) (346)
Protein synthesis in chloroplasts. I. Light-driven synthesis of the large subunit of fraction I protein by isolated pea chloroplasts. (1973) (292)
Macromolecular crowding perturbs protein refolding kinetics: implications for folding inside the cell (2000) (254)
Protein synthesis in chloroplasts: II. Light-driven synthesis of membrane proteins by isolated pea chloroplasts (1974) (247)
Protein synthesis in chloroplasts. IX. Assembly of newly-synthesized large subunits into ribulose bisphosphate carboxylase in isolated intact pea chloroplasts. (1980) (246)
Light‐stimulated transcription of genes for two chloroplast polypeptides in isolated pea leaf nuclei (1982) (232)
Protein synthesis by isolated chloroplasts (1977) (212)
Molecular chaperones: assisting assembly in addition to folding. (2006) (205)
ATP induces large quaternary rearrangements in a cage-like chaperonin structure (1993) (200)
Molecular cloning and sequencing of cDNA encoding the precursor to the small subunit of chloroplast ribulose-1,5-bisphosphate carboxylase (1980) (196)
Molecular Chaperones: The Plant Connection (1990) (192)
The molecular chaperone concept. (1989) (156)
The general concept of molecular chaperones. (1993) (151)
Protein misassembly: macromolecular crowding and molecular chaperones. (2007) (144)
Medicine: Danger — misfolding proteins (2002) (133)
Does Cycloheximide inhibit Protein Synthesis specifically in Plant Tissues? (1969) (116)
Dissociation of the ribulosebisphosphate-carboxylase large-subunit binding protein into dissimilar subunits. (1987) (108)
Processing of small subunit precursor of ribulose bisphosphate carboxylase and its assembly into whole enzyme are stromal events (1979) (98)
BIOCHEMISTRY OF PROTEIN SYNTHESIS IN PLANTS (1972) (95)
Protein synthesis in chloroplasts. V. Translation of messenger RNA for the large subunit of fraction I protein in a heterologous cell-free system. (1975) (94)
Molecular Chaperones: Opening and closing the Anfinsen cage (1994) (91)
Ribonucleic acid synthesis in chloroplasts. (1973) (87)
Inhibition of chloroplast protein synthesis by lincomycin and 2-(4-methyl-2,6- dinitroanilino)-N-methylpropionamide (1975) (85)
Sites of synthesis of chloroplast proteins. (1971) (84)
Roles of molecular chaperones in protein folding (1994) (82)
Molecular chaperones: Avoiding the crowd (1997) (76)
Protein Folding: Importance of the Anfinsen Cage (2003) (74)
The biosynthesis of ribulose bisphosphate carboxylase. Uncoupling of the synthesis of the large and small subunits in isolated soybean leaf cells. (1979) (66)
Molecular chaperones: Pathways and networks (1999) (64)
Protein synthesis in chloroplasts. Characteristics and products of protein synthesis in vitro in etioplasts and developing chloroplasts from pea leaves. (1975) (63)
The molecular chaperone concept. (1990) (56)
Rapid modulation of transcription of nuclear genes encoding chloroplast proteins by light (1985) (55)
Molecular chaperones: Inside and outside the Anfinsen cage (2001) (52)
Biochemistry: Tackling unintelligent design (2010) (52)
Protein folding and misfolding inside and outside the cell (1998) (50)
Assembly chaperones: a perspective (2013) (45)
Protein synthesis in chloroplasts. IV. Polypeptides of the chloroplast envelope. (1975) (45)
The Rubisco large subunit binding protein (1986) (45)
Chaperone substrates inside the cell. (2000) (41)
Discovery of molecular chaperones. (1996) (35)
Chaperomics: In Vivo GroEL Function Defined (2005) (30)
Do molecular chaperones have to be proteins? (1997) (29)
A good antisense molecule is hard to find (1998) (28)
Photoregulation of plant gene expression (1986) (26)
Protein synthesis in chloroplasts. VIII. Differential synthesis of chloroplast proteins during spinach leaf development. (1980) (25)
Effect of Mg2+ on excitation energy transfer between LHC II and LHC I in a chlorophyll‐protein complex (1987) (24)
Light-driven synthesis of the large subunit of fraction I protein by isolated chloroplasts. (1972) (24)
Chaperones: needed for both the good times and the bad times (2013) (24)
Protein folding: Inside the cage (2006) (24)
Chaperonins: Introductory Perspective (1996) (23)
From Chloroplasts to Chaperones: How One Thing Led to Another (2004) (22)
Chaperonin nomenclature (1993) (22)
The Rubisco subunit binding protein (1988) (21)
Amino acid sequence of the small subunit of ribulose-1,5-bisphosphate carboxylase of Pisum sativum (1981) (21)
Molecular chaperones: Plugging the transport gap (2003) (21)
Chaperoning nascent proteins (1994) (20)
Chemical synthesis of 10 kDa chaperonin Biological activity suggests chaperonins do not require other molecular chaperones (1991) (20)
Chaperone function: cracking the second half of the genetic code (1991) (20)
Sites of synthesis of chloroplast proteins. (1971) (18)
The carboxylase-large-subunit-binding protein: photoregulation and reversible dissociation. (1986) (18)
Folding and binding: problems with proteins. (2000) (18)
Immunological studies on the light‐harvesting polypeptides of photosystems I and II (1986) (18)
Synthesis, Transport and Assembly of Chloroplast Proteins (1980) (16)
The nature and function of chloroplast protein synthesis. (1973) (16)
Protein synthesis in chloroplasts. VII. Initiation of protein synthesis in isolated intact pea chloroplasts. (1976) (15)
Coprecipitation of Mitochondria and Chloroplasts (1961) (15)
Molecular Chaperones and Cell Signalling: Chaperone Function: The Orthodox View (2005) (15)
Protein Aggregation: Opposing Effects of Chaperones and Crowding (2011) (15)
Chloroplast protein synthesis: principles and problems. (1983) (14)
FRACTION I PROTEIN (1976) (13)
2 – CHLOROPLAST PROTEINS AND THEIR SYNTHESIS (1977) (11)
The Synthesis of Chloroplast Proteins (1977) (10)
Sequence does specify protein conformation. (1998) (10)
The Synthesis of Chloroplast Membranes in Pisum sativum (1975) (10)
Photoregulation of Gene Expression during Chloroplast Biogenesis (1984) (10)
Protein Folding and Chaperones (2006) (7)
The Biogenesis of Chloroplasts: Protein Synthesis by Isolated Chloroplasts (1974) (7)
Solubilization of the Membrane-Bound Deoxyribonucleic Acid-Dependent Ribonucleic Acid Polymerase of Pea Chloroplasts (1973) (7)
Obituary: Oleg Ptitsyn (1929-99) (1999) (7)
Science Fiction Roots and Branches: Contemporary Critical Approaches (1990) (7)
Further similarities between chloroplast and bacterial ribosomes. (1970) (6)
THE SEARCH FOR PLANT MESSENGER RNA (1976) (6)
The Rubisco Large Subunit Binding Protein — A Molecular Chaperone? (1987) (5)
The chaperone function: meanings and myths. (2008) (5)
Science Fiction Roots and Branches (1990) (4)
Protein synthesis by etioplasts. (1977) (4)
Chaperonin duet (1993) (4)
Molecular Chaperones and Chloroplast Biogenesis (1990) (3)
How Science Works: Evolution: A Student Primer (2010) (3)
Opening and closing the Anfinsen cage Dynamic interactions between chaperonins allow newly synthesized polypeptides to begin correct folding inside a transiently closed cage. Specialized chaperonins may be used to deal with recalcitrant proteins. (1994) (3)
The function of chloroplast ribosomes. (1972) (3)
Photoregulation of transcription of the nuclear and chloroplast genes for ribulose bisphosphate carboxylase (1984) (2)
Moledular chaperones ten years. Introduction. (2000) (2)
Philosophical Transactions of the Royal Society of London. Series B: Biological Sciences: 356 (1406) (2001) (2)
Impropriety in proteins (1990) (2)
Nuclear-Chloroplast Interactions In Chloroplast Development (1983) (2)
Chaperones of the cell (1990) (2)
Introduction: principles of chloroplast biogenesis (1984) (2)
Lincomycin as a chloroplast probe. (1971) (2)
Chaperoning protein repair (1991) (2)
The synthesis of a discrete high-molecular-weight ribonucleic acid species by isolated chloroplasts. (1972) (2)
The sites of synthesis of chloroplast proteins. (1971) (1)
Photocontrol Of Expression Of Nuclear Genes For Chloroplast Proteins (1983) (1)
Photosynthesis: Physical mechanisms and chemical patterns: by R K Clayton. pp 281. IUPAB Biophysics Series; 4. Cambridge University Press. 1980. £17.50 (hardback)/£6.95 (paperback) ISBN 0‐521‐22300‐8/0‐521‐29443‐6 (1982) (1)
Darwin’s Theory of Evolution (2010) (1)
Processing and assembly of chloroplast proteins. (1988) (1)
Nuclear-plastid interactions in plastid protein synthesis. (1979) (1)
Revisiting the Anfinsen cage. (1996) (1)
EXPRESSION OF NUCLEAR GENES FOR CHLOROPLAST PROTEINS (1981) (1)
Foreword (0)
Biological Warfare Research: The Means To Counter The Biological Weapon Threat (2013) (0)
History of the molecular chaperone concept: roles in assembly processes (2007) (0)
Two Ways of Explaining the Universe (2016) (0)
The Evolution of Eyes (2010) (0)
Infection: Prion identity wrongly credited (2014) (0)
Plant Breeding and Whole-System Crop Physiology. By D. H. Wallace and W. Yan. Wallingford, UK: CAB IINTERNATIONAL (1998), pp.390, £55.00. ISBN 0-85199-265-X. (1999) (0)
The Evidence for Evolution (2010) (0)
Protein folding Inside the cell: macromolecular crowding and protein aggregation (2007) (0)
Protein folding. Chaperonin duet. (1993) (0)
SECTION 1 Molecular Chaperones and the Cell Stress Response (2005) (0)
Two Ways of Explaining the World (2010) (0)
Developments in plant molecular biology (1980) (0)
Protein transport across membranes: an introduction. (1981) (0)
How Science Works (2010) (0)
DnaK/DnaJ Proteins (2002) (0)
On the occurrence of similar traits in related organisms (2010) (0)
Stress Proteins as Molecular Chaperones (2020) (0)
Some Major Events in Evolution (2016) (0)
Molecular Chaperones and the Cell Stress Response (2011) (0)

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What Schools Are Affiliated With R. John Ellis?

R. John Ellis is affiliated with the following schools: