Combined therapy is currently a popular method for increasing the efficiency of antitumor treatment. It involves the use of two different tumor treatment methods, namely, chemotherapy and PDT. Combining a cytotoxic agent and a photosensitizer in a single molecule results in a synergistic antitumor effect that overcomes the multiple drug resistance and reduces the therapeutic drug doses. In this work, pyridine-containing natural chlorins were obtained by introducing a pyridine group into 131-[Formula: see text]-(4-aminobutyl)amide of chlorin [Formula: see text] and its bacteriochlorin analogue, [Formula: see text]-propyloxime-[Formula: see text]-propoxybacteriopurinimide as well as [Formula: see text]-aminobacteriopurinimide methyl ester. Moreover, a terpyridine residue was introduced as an external chelating moiety into [Formula: see text]-hydroxypurpurinimide and [Formula: see text]-aminobacteriopurinimide, and platinum complexes of all the above photosensitizers were obtained. The interactions of the latter with DNA were simulated and the lead compound, the platinum complex of pyridine derivative 131-[Formula: see text]-(4-aminobutyl)amide chlorin [Formula: see text], which may become a potential agent for combined photodynamic and chemotherapy in oncology, was selected. The ability of the compounds obtained to manifest photodynamic and chemocytotoxic effects on tumor cells of various genesis was shown.