Ribosomes are heterogeneous for neutrons because RNA and proteins have different neutron-scattering-length densities. This heterogeneity is an obstacle to the shape determination of single ribosomal components within the ribosome. Therefore, we homogenized (matched) the neutron-scattering-length densities of RNA and proteins. 23S and 5S RNA from the large ribosomal subunit were isolated from cells grown in a medium containing 76% 2H2O. The total protein fraction of the large ribosomal subunit was isolated from cells grown in a medium containing 84% 2H2O. When these constituents were used for total reconstitution of 50S subunits, neutron scattering measurements of the reconstituted particles revealed excellent matching near 100% 2H2O. A three-step reconstitution procedure was developed that allowed the reconstitution of 50S subunits from deuterated RNA, deuterated total (i.e., unfractionated) proteins, and single protonated proteins. The reconstituted particles contain one protonated protein or two in a matched ribosomal matrix and were used for shape determination or distance measurement of mass centers of gravity, respectively. The signal/noise ratio is high enough to allow measurement in solutions containing nearly 100% 2H2O at concentrations of only 300-500 A260 nm units/ml. Our experiments have proved the feasibility of our biochemical strategy. The shape determinations of ribosomal proteins in situ gave radii of gyration for L1, L3, L4, and L23 of 26 +/- 2, 22 +/- 2, 20 +/- 2, and 13 +/- 2 A, respectively.