Chondrocladia lyra, also known as the harp sponge, is a species of carnivorous deep-sea sponge first discovered off the Californian coast living at depths of 10,800–11,500 feet (3,300–3,500 m) by Welton L. Lee, Henry M Reiswig, William C. Austin, and Lonny Lundsten from the Monterey Bay Aquarium Research Institute (MBARI).  
C. lyra is named the harp sponge because of its basic structure resembles a harp or lyre. It is a sessile organism which anchors itself to the soft seafloor using a rhizoid, a root-like structure that embeds into the sea floor. From the top of the rhizoid, 1 to 6 horizontal, equidistant stolons with vertical branches form the 'vanes' of the sponge (this is evident in all of Chondrocladia). Depending on the number, the vanes display pentaradiate, tetra radiate, or biradiate symmetries.  The vanes give C. lyra its harp-like structure and these are covered in velcro-like hooks and spines, which it uses to snare prey that drift past it in currents.  Of the specimens found, the largest recorded is nearly 60 centimeters in length.
Typical sponges are suspension feeders, filtering bacteria and microscopic organisms from the surrounding water through their aquiferous system. C. lyra and other carnivorous sponges, however, capture much larger prey, like copepods and other crustaceans, with the velcro-like hooks on external body surfaces. Once the hooks have ensnared the sponge's prey, is secretes a digestive membrane that surrounds and engulfs the captured prey, breaking it down until the C. lyra can absorb it through its pores.. 
The vertical branches of the harp sponge are support for filaments and terminal balls. The terminal balls are relatively large, spherical casings full of spermatophores that can fertilize other harp sponges. The spermatophores are released by the terminal balls, and sigmas protruding from the sperm are caught by protruding isochelae on the filaments. The wide frame of C. lyra optimizes the chances for successful fertilization. It allows the sponge's sperm to have a wider range when traveling downstream. The harp sponge is also better at catching sperm, due to the widened stolons thoroughly lined with filaments. When the filaments snare spermatophores, they fuse with the recipient tissues. This reaction shows a swelling in the related tissues, making fertilization evident. From these areas oogenesis occurs, followed by the maturation of the oocytes. 
C. lyra has been found in the northeast Pacific Ocean, off the coast of northern California at the Escanaba Ridge and the Monterey Canyon. It lives in soft abyssal sediment at depths between 3316 and 3399 meters and attaches to the seafloor using its root-like rhizoid. They have been seen rooted on the sides of slopes and bottom of the Monterey Canyon, where its prey is funneled into the narrow crevasses the sponges inhabit. While it has only been observed off northern California, it likely has a much wider latitudinal range of 1600km or more. 
- "Catalogue of Life: 18th April 2013". ETI BioInformatics. Retrieved 8 May 2013.
- Welton L. Lee, Henry M. Reiswig, William C. Austin & Lonny Lundsten (2012). "An extraordinary new carnivorous sponge, Chondrocladia lyra, in the new subgenus Symmetrocladia (Demospongiae, Cladorhizidae), from off of northern California, USA". Invertebrate Biology 131 (4): 259–284. doi:10.1111/ivb.12001.
- Damiel Gayle (6 November 2012). "Extraordinary harp-shaped carnivorous sponge discovered living on the Pacific Ocean floor". Daily Mail. Retrieved 6 November 2012.
- Becky, Crew. "New carnivorous harp sponge discovered in deep sea". nature publishing group. Retrieved 7 April 2013.
- "Invertebrate Biology". American Microscopical Society, Inc. Retrieved 8 May 2013.
- Charie, Wells. "Scientists discover new meat-eating, harp-shaped sponge". NYdailynews.com. Retrieved 7 April 2013.
- Natali, Anderson. "Extraordinary New Sponge Species Discovered". Sci-News.com. Retrieved 7 April 2013.
- Lee, Welton. "Invertebrate Biology". John Wiley and Sons, Inc. Retrieved 7 April 2013.
- pskhun. "Species New to Science". Retrieved 7 April 2013.