AN ANALYSIS OF THE SEQUENCES OF THE VARIABLE REGIONS OF BENCE JONES PROTEINS AND MYELOMA LIGHT CHAINS AND THEIR IMPLICATIONS FOR ANTIBODY COMPLEMENTARITY

doi:10.1084/jem.132.2.211

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AN ANALYSIS OF THE SEQUENCES OF THE VARIABLE REGIONS OF BENCE JONES PROTEINS AND MYELOMA LIGHT CHAINS AND THEIR IMPLICATIONS FOR ANTIBODY COMPLEMENTARITY

Tai Te Wu Ph.D.¹ and Elvin A. Kabat Ph.D¹

¹ From the Departments of Microbiology, Neurology, and Human Genetics and Development, College of Physicians and Surgeons, Columbia University, and the Neurological Institute, Presbyterian Hospital, New York 10032; the Biomathematics Division, Graduate School of Medical Sciences, Cornell University and the Sloan-Kettering Institute, New York 10021

In an attempt to account for antibody specificity and complementarityin terms of structure, human $kappa$ -, human $lambda$ -, and mouse $kappa$ -Bence Jonesproteins and light chains are considered as a single populationand the variable and constant regions are compared using thesequence data available. Statistical criteria are used in evaluatingeach position in the sequence as to whether it is essentiallyinvariant or group-specific, subgroup-specific, species-specific,etc.

Examination of the invariant residues of the variable andconstant regions confirms the existence of a large number ofinvariant glycines, no invariant valine, lysine, and histidine,and only one invariant leucine and alanine in the variable region,as compared with the absence of invariant glycines and presenceof three each of invariant alanine, leucine, and valine andtwo each of invariant lysine and histidine in the constant region.The unique role of glycine in the variable region is emphasized.Hydrophobicity of the invariant residues of the two regionsis also evaluated. A parameter termed variability is definedand plotted against the position for the 107 residues of thevariable region. Three stretches of unusually high variabilityare noted at residues 24–34, 50–56, and 89–97;variations in length have been found in the first and thirdof these. It is hypothesized that positions 24–34 and 89–97contain the complementarity-determining residues of the lightchain—those which make contact with the antigenic determinant.The heavy chain also has been reported to have a similar regionof very high variability which would also participate in formingthe antibody-combining site. It is postulated that the informationfor site complementarity is contained in some extrachromosomalDNA such as an episome and is incorporated by insertion intothe DNA of the structural genes for the variable region of shortlinear sequences of nucleotides. The advantages and disadvantagesof this hypothesis are discussed.

Submitted on March 25, 1970

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