following 26 genera and 35 species have   Chhongtash Formation of Karakoram   of Asselian to Artinskian age (ca. 299–276
         been identified from the Tirit Bridge locality   (Upadhyay et al., 1999b), Salt Range in   Ma, early Permian) and record this age for
         (Fig. 3A):  Barakarites densicorpus  Tiwari,   Pakistan (Balme, 1970), Tethys Himalaya   the first time, from the entire length and
         1965; Crescentipollenites korbaensis (Tiwari)   (Gothan and Sahni, 1937), Arunanchal   width of Indus-Shyok sutures across the tec-
         Bharadwaj, Tiwari and Kar, 1974; Distriatites   Pradesh (Srivastava and Bhattacharyya,   tonic collage of India-Asia continental colli-
         bilateris Bharadwaj, 1962; Faunipollenites   1996), Antarctica (Barrett and Kyle, 1975),   sion. It is remarkable to note that the palyno-
         varius Bharadwaj emend. Tiwari et al., 1989;   Australia (Kemp et al., 1977), South Africa   flora assemblages have a strong affinity to
         Ibisporites diplosaccus Tiwari, 1968;   (Manum and Tien, 1973), and South America   those that were recorded from the Lower
         Lacinitriletes badamensis Venkatachala and   (Souza, 2006).            Gondwana stratigraphic units of peninsular
         Kar, 1965; Lahirites parvus Bharadwaj and   The assemblage at the Skuru locality   India and in other Gondwanic domains
         Salujha, 1964; Lunatisporites sp., Parasaccites   (Fig.  3B)  is  dominated  by  a  non-striate   (Upadhyay et al., 1999b; Gothan and Sahni,
         korbaensis Bharadwaj and Tiwari, 1964;   bisaccate pollen grain and is represented   1937; Potonié and Lele, 1961; Balme, 1970;
         Platysaccus brevizonatus  Tiwari,  1968;   by:  Faunipollenites  varius Bharadwaj and   Manum  and  Tien,  1973;  Barrett  and  Kyle,
         Plicatipollenites trigonalis Lele, 1964;   Salujha emend. Tiwari et al., 1989; F. perex-  1975; Kemp et al., 1977; Kyle, 1977;
         Potonieisporites mutabilis Lele and Chandra,   iguus Bharadwaj and Salujha emend. Tiwari   Backhouse, 1991; Tiwari and Tripathi, 1992;
         1971; Primuspollenites, Rhizomaspora indica,   et al., 1989;  F. magnus (Bose and Kar)   Srivastava and Bhattacharyya, 1996; Souza
         Scheuringipollenites tentulus Tiwari, 1973;   Tiwari and Vijaya, 1989;  F. goraiensis   and Marques-Toigo, 2003; Souza, 2006, and
         Striatites subtilis  Bharadwaj  and  Salujha,   Potonie and Lele, 1961; F. congoensis (Bose   references therein).
         1964; Striasulcites ovatus Venkatachala and   and Kar) Tiwari et al., 1989; Ibisporites dip-  Keeping in mind the global significance
         Kar, 1968; Striatopodocarpites gondwanen-  losaccus Tiwari, 1968; Parasaccites obscures   of the Permian period of Gondwana super-
         sis Lakhanpal, Sah and Dube, 1960; and   Tiwari, 1965;  Platysaccus hingirensis   continent with regard to the palaeogeo-
         Verticipollenites secretus Bharadwaj, 1962.   Tiwari, 1968; Rhizomaspora indica Tiwari,   graphic evolution of the Asian margin dur-
         The genera found within the count (Fig. 3C)   1965;  Scheuringipollenites barakarensis   ing the late Palaeozoic to Palaeogene, it is
         are Callumispora (3%–8%);  Parasaccites   Tiwari, 1973; S. minutes (Sinha) Bharadwaj   prudent to denote that the existence of
         (10%–15%);  Plicatipollenites (8%–12%);   and Dwivedi, 1981;  S. maximus  (Hart)   Permian rocks, together with Palaeozoic
         Potonieisporites (5%–10%);  Rhizomaspora   Tiwari, 1973; and Striomonosaccites ova-  biogeographic data, firmly establishes a
         (2%–3%);  Primuspollenites  (1%–2%);   tus Bharadwaj, 1962, besides the occurrence   Gondwanan origin for most of the peri-
         Faunipollenites (2%–5%); Striatopodocarpites   of Platysaccus Naumova emend. Potonie and   Gondwanian (Cimmerian) microcontinents.
         (3%–5%); Striatites (2%–3%); Scheuring-  Klaus,  1954;  Rhizomaspora  Wilson, 1962;   In particular, the identification of extensive
         ipollenites (3%–4%); Vesicaspora (2%–4%);   Striasulcites Venkatachala and Kar, 1968 and   Early Permian pebbly mudstones in the
         Striasulcites (1%–3%); Crescentipollenites   Striatopodocarpites Soritscheva and Sedova   region and the subsequent interpretation of
         (2%–3%);  Hamiapollenites (1%–2%);   emend. Bharadwaj, 1962. The palynofloral   these pebbly mudstones as glacial-marine
         Distriatites (2%–3%); and the sporadic taxa   assemblage is dominated by nonstriate bisac-  deposits (Stauffer and Lee, 1986; Metcalfe,
         (0%–1%) includes  Lacinitriletes,  Vertici-  cate pollen  Scheuringipollenites (40%) and   2006, and references therein). Therefore,
         pollenites, Barakarites, Leiotriletes, Verru-   striate bisaccate pollen  Faunipollenites   based on the assumption mentioned above,
         cosisporites,  Ibisporites,  Lunatisporites,   (35%), Ibisporites (3%), monosaccates pollen   we suggest that the early Permian palyno-
         Sahnites,  Caheniasaccites,  Corisaccites,   Parasaccites (8%–10%), whereas the forms   morphs bearing tectonic sliver of deformed
         Ginkgocycadophytus, and Tetraporina (Figs.   Platysaccus, Rhizomaspora, Striasulcites and   pebbly mudstone, which is entrapped in the
         3A and 3C).                         Striatopodocarpites are sporadic (1%–2%)   Ophiolitic Mélange of the Shyok Suture,
          The dominance of Parasaccites and sub-  (Fig. 3B).                    have a close affinity to those of peri-
         dominance  of  Plicatipollenites in Tirit   The dominance of nonstriate bisaccate   Gondwanian (Cimmerian) origin.
         Bridge  samples point  to an Asselian age   pollen Scheuringipollenites (40%) and stri-  It is well known that the peri-Gondwanan
         (early  Permian;  299–297  Ma);  however,   ate bisaccate pollen Faunipollenites (35%)   (Cimmerian) tectonic elements and early
         the presence of monosaccates (Parasaccites,   in the Skuru samples favors an Artinskian   Permian exposures are well distributed in
         Plicatipollenites) in association with   (late Cisuralian, ca. 284–276 Ma) age.   the Shyok Suture vicinity; i.e., the Karakoram
         Callpumispora spp.  Faunipollenites spp.,   These palynofloral assemblages are similar   terrane to the north and the Qiangtang-Lhasa
         Straitopodocarpites spp., Crescentipollenites   to those established from the Barakar   blocks to the ENE and ESE, respectively. It is
         spp., and the First Appearance Datum   Formation of Gondwana assemblage of   quite evident that a thin flake of active
         (FADs) species of Barakarites gondwanen-  India (Tiwari and Tripathi, 1992); Antarctica   continental margin of these peri-Gondwanic
         sis Maithy, 1965, and Scheuringipollenites   (Kyle, 1977); Collie Basin Australia (Kemp   microcontinents/Kshiroda plate (Jagoutz et
         barakarensis  Tiwari, 1973, points to a   et al., 1977); Ketawaka and Songwe-Kiwira   al., 2015) were sliced off during the course of
         Sakmarian age  (early Permian; 297–284   Coalfield in Tanzania, Africa (Manum and   the subduction/collision process, between
         Ma). The aforementioned palynofloral   Tien, 1973); and South America (Souza and   Ladakh and Karakoram–Qiangtang-Lhasa
         assemblage is similar to those observed   Marques-Toigo, 2003).        blocks, and amalgamated with obducted
         from the  Parasaccites korbaensis zone                                 remnants of accretionary prism of the
         (Tiwari and Tripathi, 1992) of Upper Talchir   TECTONIC IMPLICATION    nascent  Shyok  Suture. The  Shyok  Suture
         (Asselian) and the Karharbari Formation   The palynoflora assemblages from the   closed during the mid- to Late Cretaceous
         (Sakmarian) of Gondwana assemblage of   pebbly mudstone unit of the Shyok Suture   period. Subsequent syn- and post-collision
         peninsular India (Potonié and Lele, 1961),   Zone (Figs. 1–3) dates these metasediments   synkinematic episodes were responsible for

         8  GSA TODAY  |  January 2022