Navigate the challenges of modern life, with ancient and time-tested Greek and Roman thinkers at your side.

What is a good life? And how can we create that life in a world filled with uncertainty? Beyond Stoicism invites you to find your own answers to these big questions with help from thirteen of the most prominent Greco-Roman philosophers―many of whom inspired, or were inspired by, the Stoics.

By taking cues from the lives and ideas of the Cynics, Epicureans, and others, you’ll learn to:

• Seek pleasure with Aristippus
• Strike the right balance with Aristotle
• Focus on what’s up to you with Epictetus
• Be a rebel like Hipparchia
• Embrace uncertainty with Carneades
• Question everything with Socrates
• Work toward a just society with Plato and much more

Times have changed, but the quest for eudaimonia―a life worth living―stays the same: We still seek pleasure and crave love, avoid pain and fear death. That’s why all these ancient sages can continue to guide us, practicing Stoics and new seekers alike.

William C. Taylor Department of Genetics University of California Berkeley, California 94720 It is evident by now that there is a great deal of interest in exploiting the new technologies to genetically engineer new forms of plants. A purpose of this meeting is to assess the possibilities. The papers that follow are concerned with the analysis of single genes or small gene families. We will read about genes found within the nucleus, plastids, and bacteria which are responsible for agri culturally important traits. Given that these genes can be isolated by recombinant DNA techniques, there are two possible strategies for plant engineering. One involves isolating a gene from a cultivated plant, changing it in a specific way and then inserting it back into the same plant where it produces an altered gene product. An example might be changing the amino acid composition of a seed pro tein so as to make the seed a more efficient food source. A second strategy is to isolate a gene from one species and transfer it to another species where it produces a desirable feature. An example might be the transfer of a gene which encodes a more efficient pho tosynthetic enzyme from a wild relative into a cultivated species. There are three technical hurdles which must be overcome for either strategy to work. The gene of interest must be physically isolated.